SU654965A1 - Demagnetizer - Google Patents

Description

It is advisable to close the magnet 1 from the inner diameter side with the magnetic core 2 in order to increase the magnetic field strength in the region of the demagnetized product.

The magnetic core 2 is in the form of a magnet of a soft, magnetically unsaturated steel cylinder or tube.

The product being demagnetized (e.g., a demagnetizing tape) moves along a non-magnetic restrictor 3.

The sizes of the magnet and the largest parts of the sectors of one direction of magnetization are chosen from the following considerations.

The second sector of one direction of the strongest magnetization on the ring, its height and width must be such that the magnetic field strength at the surface facing the demagnetized surface is equal to the magnetic field strength determined from the intersection of the limit magnetization curve (in the first square of the graph magnetic hysteresis of the material of the body to be demagnetized) and the dummy load line drawn from the origin, the tangent of which the angle of inclination is given by the value of the demagnetization present article factor to be demagnetized. The first sector of one direction of magnetization of the ring magnet 1 must be greater than or equal to the angular extent and absolute magnitude of the magnetization of the second sector, but the direction of magnetization of the latter is opposite to the direction of magnetization of the first sector. The required number of sectors of the magnet 1, magnetized oppositely adjacent, depends on the permissible level of residual magnetization of the bodies to be demagnetized.

The lower this permissible level, the greater the average radius, the ring should be chosen and magnetised by a larger number of sectors.

It is possible to magnetize radially across sectors a radiated ring of ferrite ring, supplying to its outer diameter magnetic cores transmitting flows from a source of strong magnetic field, having a zero, equal to sectors of one direction of magnetization.

With such magnetization, it is advisable to close the magnet 1 by its internal diameter with a POLE jumper, opposite the magnetized sectors.

To limit the scattered fields of magnet 1 (and simultaneously increase the operating fields) from the outside with respect to the parts to be demagnetized and the magnet parallel to the stopper 3, a soft magnetically unsaturated screen similar to this part along the magnet profile can be installed. Such a screen without increasing

significantly complexity of the system, allows to significantly reduce the size (and hence the cost) of the most expensive part of the de-magnetizer - a permanent magnet. In order to ensure the most complete demagnetization of the product (for example, hardened steel balls for ball bearings after grinding using a device that keeps them machined by a magnetic field), it is advisable to use the variant shown in FIG. 2

Here, the stopper 3 is made in the form of a wall, molded or adhered to the magnet and the surrounding track 4. The wall of the stopper 3 of the movement of the demagnetized parts is made in the form of an Archimedean spiral. Moving along the wall of the limiter, the body to be demagnetized repeatedly falls into the floor of magnet 1, but, moving away from it, plunges into the floor of lesser and lesser magnitude.

If it is necessary that the magnetic scattering field of the demagnetiser is limited especially hard, it is advisable to use the variant of its implementation shown in FIG. 3. The radially magnetized reversivio over sections of the ring magnet 1 is provided with an external annular magnetic conductor 5, which is at the same time a screen that limits the field of the scattered magnet and protects it from external influences. To enter the product to be demagnetized into the working zone of the demagnetizer in magnet 1 and magnetic core 5, a gap 6 is provided.

The demagnetized product (nanometer, steel ball) introduced through the gap 6 moves along the non-magnetic wall of the limiter 3, made in the form of an Archimedean spiral, and coil after coil moves away from sector 7 with the highest magnetization. Moving along the descending track, the ball through hole 8 enters the box for demagnetized parts.

If the product to be demagnetized is a magnetic tape, then it is easy to demagnetize it, directing the tangent line to the demagnetizer shown in FIG. 1, while the magnet 1 and the magnetic conductor 2 must rotate at a speed synchronized with the speed of the tape stretching so that the tape section, but with a length equal to the circumferential length of the annular sector of the magnet 1 (but its outer diameter), will fall back by his place was taken up by the next such section during the turnover of magnet 1 with magnetic core 2.

If the horizontal position of the demagnetizer for demagnetizing the tape in the apparatus is inconvenient or it is necessary to shield its magnetic scattering flows, then it is advisable to use the option of executing the demagnetisator, shown in FIG. four.

During the rotation of the magnet 1 and the magnetic circuit 5 (synchronized with the movement of the demagnetized tape), each section of the tape is reliably demagnetized by a field varying in sign and decreasing in size when the demagnetized section of the tape is removed.

To increase the demagnetizing field in the axial part of the magnet 1, a central magnetic circuit in the form of a soft cylinder or tube can be permanently mounted.

If it is inconvenient to rotate the demagnetizer in equipment, then the tape can be demagnetized by the stationary demagnetizer shown in FIG. 5. During its movement, the demagnetized tape must make a coil in the internal channel of the demagnetizer, and the center of the coil must be shifted towards the sector with the most magnetizing and can be filled with a magnet with a soft core. When moving along the azimuth of a turn, each loop section successively falls into an alternating magnetic field of decreasing magnitude and is demagnetized. In order to increase convenience in the passage of the tape in the magnet 1 and the magnetic core 5, slot gaps may be provided.

In case of difficulties with the manufacture of a small radial-textured thin-walled magnet (when a very small field in a small volume), you can use a demagnetizer based on reverse axially magnetised and also a textured magnet; A variant of a demagnetizer based on such an annular magnet is shown in FIG. 6

The basis of the demagnetizer is a ring magnet 1, which is magnetically reversible axially across sectors.

The magnetic field on the end pole surface of the magnet is magnified by a magnetic core 5, in the axial channel of which a magnetic shielding field 9 is installed. The demagnetizing tape moves at a speed synchronized with the speed of rotation of the magnet. The section of the tape, which first falls into the area of the strong sex at the poles on the periphery (

the outer diameter of the magnet during the passage of the radius of the magnet must travel to an ever decreasing field (including due to the narrowing of the sectors of one direction of magnetization towards the center of the ring).

In some cases, the passage of the tape into the central hole of the magnet may be inconvenient, and then it is advisable to direct the tape diametrically (or almost diametrically) over the end surface of the magnet, half of the circle with each pole surface of which is closed by magnetic conductors, and the magnet itself is magnetized sequentially along sectors with decreasing magnetization up to half of the ring, and then again but on the sections from the maximum to zero. Ego makes it possible to create a convenient multi-track demagnetizer, passes

demagnetized ribbons over its different ends.

Axially magnetized. ring magnet can be the basis of a stationary demagnetizer and for demagnetization

steel balls.

Such a demagnetiser is shown in FIG. 7

Claims (2)

1. A demagnetizer containing a motion limiter of a demagnetized product and a permanent magnet magnetized in areas, one of the areas has a maximum magnetization, and each subsequent area along the direction of movement of the demagnetized product is magnetized weaker and opposite to the previous one, characterized in that, in order to miniaturize the demagnetisator, the permanent magnet is in the form of a ring, and the sections are sectors. 2. A de-magnetizer according to Claim 1, characterized in that the movement restriction of the product is designed as a non-magnetic Archimedean spiral. Sources of information taken into account in the examination 1. French patent number 2085543, cl. H 01F 13/00, 1971. 2. USSR author's certificate No. 549846, cl. H 01F 13/00, 1976. CD g / g7 a5 ipui s N