RU2036163C1 - Device for magnetic treatment of liquid - Google Patents

Abstract

FIELD: treatment of liquids. SUBSTANCE: treatment is carried out in a sleeve provided with several nonmagnetic disks. The disks reciprocate and overlap almost the whole cross- section of the sleeve. The disks are secured either to the central stand or to the wall of the inner sleeve which is inserted into the main sleeve for permitting movement. When the disk move in the axial direction, liquid flows in the space between the disks and also in radial direction which is perpendicular to the force line of the magnetic field. This flow regime and treatment of liquid are provided owing to the presence of perforation at the central part of the first disk, periphery perforation of the next disk, etc. EFFECT: enhanced efficiency. 12 cl, 7 dwg

Description

 The invention relates to the magnetic treatment of liquids and can be used mainly for batch processing of relatively small volumes in both industrial and domestic conditions.

 A device for magnetic processing that is embedded in the pipelines of water systems [1] The device is a glass, in the central part of which is placed a cylindrical magnet with a pole tip. The fluid is magnetically treated, flowing in the gap between the magnet and the glass wall.

 However, the processing efficiency in such a device is not high enough, since the fluid moves in a magnetic field either parallel to its lines of force, or crossing them at a small angle. To increase the efficiency of processing devices are arranged sequentially in sections of five pieces.

 A device for magnetic water treatment [2] consisting of a glass with a movable Central rack. At the bottom of the rack are two discs with a gap between them. Six magnets are attached to the top and bottom surfaces of each disk. Perforations are made in the discs around each magnet. Magnetic processing is carried out during the reciprocating movement of the Central rack with disks.

 The water treatment efficiency in this device is also not high enough. Water is subjected to magnetic treatment only when moving in the axial direction along the magnet and only in the area, the length of which is almost equal to the height of the magnet. To increase the processing efficiency, the device implements four consecutive sections of the same type, each of which is represented by six magnets located on one side of the disk.

 In the proposed device with a simpler design can be achieved higher efficiency of the magnetic treatment of the liquid. For this, the shape of the disks and the arrangement of the magnets are changed so that the liquid is processed when it moves in the radial direction perpendicular to the lines of force of the magnetic field. Radial fluid movement is created in the gap between the disks during their reciprocating movement, if one of the disks overlaps the entire cross section of the glass, but has a perforation for the passage of liquid in the central part. In this case, the second disk is perforated around the periphery or has a diameter smaller than that of the first disk, which allows fluid to pass between the edge of the disk and the wall of the glass.

 The orientation of the magnetic field lines perpendicular to the direction of fluid movement is achieved if the magnet is coaxial to the glass in the gap between the disks, and the disks are made of ferromagnetic material and serve as pole tips of the magnet, or if each of the disks is itself a magnet.

 There are two options for mounting discs to facilitate their reciprocating motion in a glass. In the first case, as in the device adopted for the prototype of the invention, the disks are attached to the central rack. In the second case, the disks are fastened with the outer edge to the inner glass inserted into the main glass with the possibility of movement.

 In FIG. 1 shows a device with mounting discs to a central rack; in FIG. 2 same, top view; in FIG. 3 a device in which discs are magnets; in FIG. 4 the same, top view; in FIG. 5 device with mounting discs to the inner glass; in FIG. 6, section AA in FIG. 5; in FIG. 7 device with an additional disk.

A device for magnetic processing of liquid includes a cup 1, in which there is a central rack 2, movable relative to the glass 1. In the lower part of the rack two disks 3 and 4 of ferromagnetic material are attached. Between the disks there is a gap 5, in which a magnet 6 is placed coaxially to the rack 2. The upper disk 3 and the lower disk 4 serve as pole tips of the magnet 6. In the upper disk 3, perforation 7 is made around the magnet 6 for liquid passage. On the stand 2 above the perforation 7 of the upper disk 3 there is a reflector 8. It is possible to mount the reflector 8 and directly to the upper disk 3. To prevent fluid from moving between the wall of the glass 1 and the outer edge of the upper disk 3, the latter can be provided with a sleeve 9 or have a larger diameter, than the lower disk and almost coinciding with the inner diameter of the glass 1. The disk can also be equipped with one or more check valves 10. The shape of the disks 3 and 4 can be flat or disk-shaped. The gap between the disks, at least in their peripheral part, is of the order of 10 ^-3 m. The device can also be made without magnet 6, if the disks themselves are magnets (Fig. 3).

 In the second embodiment, the design of the device for magnetic processing of liquid in the glass 1 is an inner glass 11 (Fig. 5). In the lower part of the inner cup 11, the upper and lower discs 3 and 4 are attached, as well as the magnet 6. The inner cup 11 is inserted tightly enough, but with the possibility of movement relative to the cup 1. In the upper part, the inner cup 11 protrudes above the wall of the cup 1 and can be closed lid 12. The bottom of the inner glass 11 does not have.

 The magnets in the described devices can be permanent or electromagnets.

 To further increase the processing efficiency in both versions, the magnets and / or disks can be arranged in several consecutive sections. In FIG. 7 shows a two-section device in which the second section is formed by the lower disk 4 of the first section, the second magnet 6 and the additional disk 13. For clarity, the proportions in the ratio of the diameters of the upper and lower disks 3 and 4, the gap 5 between the disks and the perforation 7 are changed.

 The device operates as follows.

 When the central rack 2 moves upward, the liquid located above the upper disk 3, under the action of gravity and vacuum, will pass through the perforation 7 in the gap 5 between the disks 3 and 4. In the gap 5 from the center to the periphery, the liquid will move in a magnetic field perpendicular to it power lines. Then, passing between the wall of the glass 1 and the lower disk 4, the liquid will fall into the space under the lower disk 4. When the rack 2 moves from the upper position down, the direction of the liquid moves in the opposite direction, but the speed of movement and, accordingly, the efficiency of magnetic processing can be significantly higher , which is determined by the force applied to the rack 2. Spatter of liquid passing upward through the perforation 7 of the upper disk 3 is prevented by a reflector 8. When the upper disk 3 is equipped with a check valve SG 10, the latter when moving upward the rack 2 is fast enough to leak down without radial movement in the gap 5, i.e. without magnetic treatment. In this case, the processing will occur when the rack 2 moves down, when the check valve is closed.

 The technical result achieved will be the same if, in the described embodiment of the design, the upper 3 and lower 4 discs are interchanged. In this case, reflector 8 will not be needed.

 The operation of the device will not change if two disk magnets are used instead of one magnet with disk pole pieces (Fig. 3).

 The operation of the device shown in FIG. 5 is similar to that described for the first embodiment, except that the reciprocating movement to the magnets and / or discs is not reported through the central rack, but through the inner cup 11. In both cases, the movement can be carried out either manually or using any convenient drive .

 During operation of two or more sectional devices (Fig. 7), the liquid will be subjected to magnetic processing, moving in adjacent sections between the disks alternately either to the center or to the periphery of the disks.

Claims (13)

 1. DEVICE FOR MAGNETIC TREATMENT OF LIQUID, including a cup, a central rack, movable relative to the cup, in the lower part of which are attached two disks with a gap between them and a magnet, at least one of the disks is perforated, characterized in that the magnet is located coaxially between the disks with a central stand and the disks are made of ferromagnetic material or the disks themselves are magnets, one of the disks is perforated in the central part, and the other is perforated around the periphery or has a diameter higher than that of the first disk.  2. The device according to claim 1, characterized in that a reflector is made over the perforation of the upper disk.  3. The device according to claim 1 or 2, characterized in that a cuff is attached to one of the disks.  4. The device according to p. 1 or 2, characterized in that the diameter of one of the disks is larger than the diameter of the other disk.  5. The device according to any one of claims 1 to 4, characterized in that one of the disks is equipped with check valves located opposite the perforation of the second disk or opposite the gap between the second disk and the glass wall.  6. The device according to p. 5, characterized in that at least one of the disks has a plate shape.  7. The device according to claim 6, characterized in that it is equipped with an additional magnet and / or disk, and the perforation on the additional disk is made in the same way as on a non-adjacent disk.  8. A device for magnetic processing of liquid, including a glass, perforated disks and a magnet mounted for movement relative to the glass, characterized in that it is additionally provided with an internal glass, a magnet is placed between the disks coaxially with the glass, one of the disks is perforated around the magnet, and the other perforated on the periphery or has a diameter smaller than that of the first disk, and the disks are attached to the lower part of the inner glass.  9. The device according to claim 8, characterized in that a reflector is made over the perforation of the upper disk.  10. The device according to claim 8 or 9, characterized in that the diameter of one of the disks is larger than the diameter of the other disk.  11. Device according to any one of paragraphs.8 to 10, characterized in that one of the disks is equipped with check valves located opposite the perforation of the second disk or opposite the gap between the second disk and the wall of the inner glass.  12. The device according to claim 11, characterized in that at least one of the disks has a disk shape.  13. The device according to p. 12, characterized in that it is equipped with an additional magnet and a disk, and the perforation on the additional disk is made in the same way as on a non-adjacent disk.

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