DE1278620B - Permanent magnet systems with reduced temperature dependence of induction - Google Patents

Description

Permanent magnet systems with reduced temperature dependence of induction The invention relates to permanent magnet systems with permanent magnets made of one material are equipped with a strongly negative temperature coefficient of induction which, however, allow at most a slight temperature dependence of the induction is. Permanent magnet materials with a strongly negative temperature coefficient of induction are for example barium ferrite, lead ferrite and strontium ferrite.

Barium ferrite of chemical composition Ba0 - 6 Fe20g has become established as a permanent magnet material in many areas of permanent magnet technology, whereby economic considerations were of crucial importance. In particular because of the strong temperature dependence of the magnetic properties of the material Certain areas of application have so far remained closed to barium ferrite. A Examples of such areas of application are measuring instruments, especially those based on moving coils, also the electricity meters and tachometers.

These are made using the much less temperature-dependent Alnico magnets the temperature errors caused by shunts with material certain known temperature dependence of the permeability is reduced. Mention should be made also some applications of holding magnet systems. Since the adhesive force is not too great Air gaps is proportional to the square of the induction and the temperature coefficient the adhesive force is slightly more than twice as great as that of induction such holding magnet systems are subject to a strong temperature dependence. These Temperature dependence is irrelevant for most holding magnet systems. It but there are also cases in which holding magnet systems operate in a very large temperature range have to work. Alnico magnets have hitherto been used in such cases.

The induction of barium ferrite permanent magnets increases with increasing Temperature and vice versa. This temperature dependence is approximately linear and amounts to 2% a / ° C temperature change. For comparison it should be mentioned that the same applies to Alnico permanent magnet materials widely used the temperature coefficient has only one tenth to one twentieth of the specified value.

The strongly negative temperature coefficient of the induction of barium ferrite is known. The proposal is also known for magnet systems with permanent magnets made of barium ferrite a temperature compensation device with magnetic shunt to provide a body made of a heat alloy that resists when the temperature increases its magnetic resistance increases, in the area of a constriction of the magnetic soft, the useful flow conducting body is arranged. This arrangement is intended to The effectiveness of the heat alloy will be increased as the density of force lines in the area the narrowing of the Nutzfiußleiter is greater than at the non-narrowed points. However, this proposal does not provide for the flow guide to be so strong burden that the maximum permeability is exceeded and the scattered fiow increases will.

According to another known proposal, the pole plates and pole shoes of a magnet system consist of different materials, which are selected in such a way that that the permeabilities under the influence of the prevailing inductions one Strive for the maximum. Also by suitable dimensioning of the cross-sections of the pole plates and pole shoes aim to achieve this goal. But even with this proposal should the maximum permeability must not be exceeded, since precisely the avoidance of Losses through litter is sought.

The invention aims, the barium ferrite and other permanent magnet materials with a strongly negative temperature coefficient of induction such new uses to develop where at most a low temperature dependence of the induction is permissible. This purpose is achieved by using permanent magnets made from such permanent magnet materials Equipped permanent magnet systems achieved in which, according to the invention, the cross-sections of the iron parts are so small that they are influenced by the ruling ones magnetic field strength the maximum permeability is exceeded. These Dimensioning of the iron guide parts, e.g. B. the pole piece, is different from the usual one, since the flux present in the permanent magnet is usually passed on with as little loss as possible and losses due to scattering are to be avoided as far as possible. at For a given flux strength, the lower the loss due to scattering, the greater the loss is the permeability of the iron conducting parts. The permeability in iron increases above the maximum permeability, depending on the type of iron, with increasing induction; the scatter increases strongly here. In the case of magnetic saturation, the permeability of the decreases Iron to the value 1. Iron then acts like air and loses its good conductivity for the magnetic flux. For this reason, when building magnet systems, the Reduction of the magnetic leakage flux the induction in the iron conductor pieces dimensioned below 12,000 G. In special cases, especially with holding magnet systems, one also went higher with induction. Here, however, was the volume saving and not the temperature dependence of induction of practical importance.

The invention is based on the idea of increasing the magnetic leakage flux, which is caused by a reduction in the cross-section of the iron conducting parts is achieved, the strong temperature dependence of induction in permanent magnet systems, those with permanent magnets with a strongly negative temperature coefficient of induction are equipped, largely to be eliminated.

In this case, the induction in the iron conductor pieces should expediently at room temperature be greater than 14,000 G or even greater than 17,000 G. With the strong temperature dependence the induction of barium ferrite and other permanent magnet materials increases with Temperature reduces the induction in the iron conductors and thus also the leakage flux. At low temperature it works because of the high induction values in the iron conductors a large part of the flux given off by the permanent magnet to the iron conductors lost as leakage flux. This loss is reduced with increasing temperature, because with decreasing flux in the permanent magnet, so does the flux and thus the induction decrease in the iron conductors and the permeability increases.

The invention is based on three magnet systems according to the drawing, in which the cross-sections of the iron guide parts are of different sizes are explained.

The magnet systems consist of a block-shaped permanent magnet A (made of barium ferrite in the dimensions 33-23.10 mm) and are magnetized in the direction of the smallest dimension, as the pole designations N, S indicate. On the ground pole faces measuring 33 - 23 mm, two iron conducting pieces B with the dimensions 40 - 23 - X mm are loosely attached, but practically without air gaps in such a way that the permanent magnetic flux runs through the iron cross-section X - 23 mm =, like the designations N and S at the ends of the iron conductor pieces B. The iron conductor pieces B are each short-circuited by an iron armature C around which a coil Sp is wound. The ends of the coil Sp are connected to a flux meter M. By pulling the permanent magnets A out of the systems, the magnetic flux 0 in Maxwell was measured with the flux meter M at temperatures between 20 and 80 ° C. By dividing the measured fluxes -P by the magnetic cross-sections of the iron conductive pieces B , the induction B in Gauss was calculated in these iron conductive pieces. Furthermore, the product B - (P was calculated as a measure of the adhesive force of the system on the anchor C. The measurements were carried out on three systems in which the thickness X of the iron conductor pieces was 4, 2 and 1 mm. The results are in of the following table of figures, which also gives the mean temperature coefficient (TC) in 0 / ", / 'C between 20 and 80 ° C. X # ö C TK from IBB. #, TB of (mm) (M) (° 100 .i ° C) (G) (GM) (o / oa / ° C) 4 14270 1.05 15 280 2.18-108 2.06 2 9020 0.67 19 200 1.72 - 108 1.34 1 4950 0.41 21500 1.07-108 0.84 The number table shows that with decreasing thickness X of the iron conductor pieces from 4 to 1 mm, the magnetic flux decreases to about a third, the induction increases from over 15,000 G to 21,500 G, but the temperature coefficient of the magnet system increases from 1.050 / 0o / 'C decreases to 0.410 / 0o / 'C. If one compares these values of the temperature coefficient with that of the induction of barium ferrite without iron conductors or with very strong iron conductors (20 / 0o / 'C) or with that of the induction of Alnico (0.1 to 0.2 "/"/' C), Thus it can be seen that the TC of barium ferrite in iron conductors with X = 1 mm has already been reduced to a fifth of its original value and that of the Alnico has almost been reached. This lowering of the TK is bought at the price of a considerable reduction in the magnetic flux, according to the number table. However, there are enough practical applications in which the volume of the barium ferrite, which can be produced relatively cheaply, is of secondary importance compared to the lowering of the TC. Since the adhesive force is proportional to the product of B - 0 , its decrease with decreasing X is not as strong as that of 0. The TK values of the adhesive forces (-B - 0) are about twice as large as those of 0 and B. For barium ferrite permanent magnets without iron conductors, compare 40/0 "/ 'C and for Alnico 0.2 to 0.40 /"/' C with the corresponding values on the number table.

The invention is not limited to the permanent magnet systems shown and explained limited. Rather, it also refers to systems whose permanent magnets come from others Materials as barium ferrite, e.g. B. lead ferrite or strontium ferrite exist that have a strongly negative temperature coefficient of induction. The supernormal Induction of the iron conducting parts should be over 12,000 G, for example over 14,000 G and can go beyond 17,000G for an even greater effect. It is also sufficient to strongly taper the iron guide parts only in one or more places and so the induction at these points of the iron conducting parts above 12,000 G, preferably to increase over 14,000 G or more.

To increase the leakage flux, in addition to reducing the iron conductor cross-sections other measures are also taken. For example, can man each part of the iron conducting pieces B of the illustrated magnet system that is attached to the Iron anchor C is adjacent and does not touch permanent magnet A, enlarge it.

The iron conductor pieces B can also be wider and longer than the permanent magnet cuboids Make A so that they protrude over the edges of permanent magnet A. Also on this In this way, the leakage flux can be increased.

In order to evaluate the invention in practice, the flux law of the magnetic circuit is expediently used, according to which, if the magnetic scattering is neglected, the flux 0 ", = B", - q ", (induction times cross section) in the permanent magnet is equal to the flux OF, = BF 'is qF in Eisenleitstück. Since one B and q in the permanent magnet in most practical cases knows and also has experience of the scattering loss can q "" be selected so that the invention BF, values in excess of 12, 000, for example, of over 14,000 or even 17,000 G. At least the laws of the magnetic circuit provide a first indication of the choice of iron cross-sections according to the invention, which is often compared with the construction of test systems with slightly larger and smaller cross-sections to be corrected for the calculation.

To fully compensate for the temperature dependence of the magnet systems To achieve according to the invention, shunts can also be used in a known manner with materials that have a negative temperature coefficient of permeability, to be ordered.

Claims (2)

Claims: 1. Permanent magnet systems with permanent magnets strongly negative temperature coefficient of induction are equipped, but where at most a slight temperature dependence of the induction is permissible, d a d u r c h g e k e n n -z e i c h n e t that the cross-sections of the iron guide parts so are small that under the influence of the magnetic prevailing in them Field strength the maximum permeability is exceeded. 2. Permanent magnet systems according to Claim 1, characterized in that the induction in the iron guide parts is more than 12,000 G. 3. Permanent magnet systems according to claim 2, characterized in that that the induction in the iron conducting parts is 17,000 G or more. 4. Permanent magnet systems according to claim 1 to 3, characterized in that the leakage flux is caused by further, measures known per se is enlarged. 5. Permanent magnet systems according to claim 1 to 4, characterized in that the permanent magnets made of barium ferrite with the approximate Composition Ba0 - 6 Fe203 consist. 6. permanent magnet systems according to claim 1 to 5, characterized in that it is used to further compensate for the temperature dependence induction in a known manner a shunt made of a material with negative Have temperature coefficients of permeability. 7. Use of permanent magnet systems according to claims 1 to 6 in moving-coil measuring instruments. B. Use of permanent magnet systems according to claim 1 to 6 in measuring units, z. B. Electricity meters and tachometers, which work on the principle of eddy current damping. 9. Use of permanent magnet systems according to claims 1 to 6 as holding magnet systems. Considered publications: German Patent No. 723 328; German Auslegeschrift No. 1028 709; Technical Communications Krupp, Vol. 12, 1954, No. 2, pp. 47 to 51.