DE1671038C - Highly permeable manganese-zinc ferrite core - Google Patents

Description

The invention relates to ferromagnetic ferrite Curie points between 20 and UO ⁰ C and the material cores based on manganese, zinc and iron oxide with one of the other core having a Curie point above HO ⁰ C

high initial permeability of several thousand. The further inventive

There are already manganese-zinc-ferrite cores with a high level of teaching, but leads beyond the known state Initial permeability on the order of 5 of the technique. Only their combination with the

μ = 1000 to 10 000 known that one or more previously known partial features is capable of the

Permeability maxima depending on the object underlying the invention completely

have temperature. The disadvantage of this highly permeable,

blen ferrite cores consists in the fact that the Curie temperature is expediently the interfaces between the two an upper limit for the ferromagnetic effective xo single cores, d. H. the surfaces in which the individuality represents and the highest initial barrier cores come into contact with each other, essentially usually immediately below this Curie loan along the one that runs in the operating state temperature occur. This means that the magnetic field lines are applied. This becomes possible use such ferrite cores avoided in one that a not insignificant proportion magnerelativ large temperature range set 15 table field lines from one single core to the other are, since the Curie temperature is not exceeded, single core is exceeded, which is usually disadvantageous which may also lead below these so-called results. Even with a very smooth surface the first permeability maximum would have been partially “sheared” the entire core, lower permeability values occur. The development so that the initial permeability of the core material, development of ferromagnetic ferrites of this type with a 20 that is measured on the total core, not the core secondary and so-called tertiary permeability.

It is true that the initial permeate was able to achieve a maximum of quality. It is particularly advantageous if the cohesion also in a relatively larger temperature settlements for the starting substances of both individual areas still to be kept relatively high, the requirement cores are selected in such a way that the individual cores genes, which through various new techniques at high »5 their secondary and tertiary permeability maxima permeable ferrite cores are made, these are possess at different temperatures. Through this known manganese-zinc ferrite cores, however, will still have a more or less strong compensation not fully grown. To these techniques of counting maxima and minima in permeability temp among other things: deep temperature process, room temperature curve achieved and the temperature-dependent vehicle control, Lows. 30 speed reduced in the operating temperature range.

The invention is based on the idea of forming the cores as toroidal cores-manganese-zinc-ferrite with at least two individual cores and to create two or more single cores with different zinc content in individual cores of the same or different height otherwise to be used in a temperature range between about -50 and the same dimensions. The windings + 100 ° C have a high initial permeability of more than 35 then over all .; Cores placed so that as μ has _α = 5000 with low losses. Each core is magnetized in the same way. Such ferrite cores are to be used in particular for broadband single cores in a further development of the invention with transducers, pulse transducers, power transmitters at approximately the same Curie temperature, but at higher frequencies, and indeed also with different positions of the maximum permeability, if these devices can achieve considerable temperatures the permeability-temperature curve are exposed to fluctuations. Circumstances are equalized to such an extent that no

In order to solve the problem, the established secondary or tertiary maxima provide, despite the fact that the starting substances for the high initial permeability of the total core occur in individual cores less than 0.05 percent by weight over a wide temperature range. Have a spontaneous velvet impurities and are selected from the following 45 tanes decrease in total permeability by AusRbereich: If the one core with the lower Curie 51.5 to 53.0 mol percent Fe ₂ O ₃ temperature then also does not take place.
20 to 30 mol percent ZnO, ^{with reference to F} '8-1 to 6, the exemplary embodiments 17 to 28.5 mol percent MnO. ^{represent for the} invention, this is explained in more detail in the following '50.

It has surprisingly been found that in In the FIG. 1 is a transformer with an inven-

Application of the teaching according to the invention, the ferrite core according to the invention shown above in section. the

the problem can be solved successfully and the transformer is made up of two toroidal cores 1, 2 of the same

the solution of the given task, d. H. composed of one measurements, and both toroidal cores

Very large temperature range of about 150 ° C, 55 are surrounded by common windings 3, by

gives a very high initial permeability. which the connecting lines 4 to the corresponding

The use of pure starting substances is leading to contact points. Bobbin and fastening! »·

already known per se, and it is also known that, for the sake of clarity, the organs are not

If necessary, ferromagnetic cores are made from different. The single core 1 has a composition

Layers, for example with different zinc 60, which are shown in the three-substance diagram 5 of FIG. 2 with the

content and with different effective permeability point \ A is shown. The single core 2 has the

lity to train in order to achieve a desired permeability point IA according to FIG. 2 corresponding combination

development within a relatively small company. The composition relates

temperature range to be reached. Two should each be based on the weight of the oxide mixtures,

or several matching partial cores made of 65. .

Nickel-zinc ferrite with different temperatures- Example A

coefficients of permeability combined.

t earth, the material of one core having a size 1 A of 52 mol percent FejO ₃ , 28 mol-

percent ZnO and 20 mol percent MnO, the composition 2 A consists of 53 mol percent Fe, O _a , 26 mol percent ZnO and 21 mol percent MnO, the non-ferrite-forming impurities in both individual cores are less than 0.02 percent by weight. The Curie temperatures (T _e ) of the two individual nuclei are 75 and 105 ⁰ C.

Beiiic single cores are manufactured in the same way. The oxide mixtures in question are ^{calcined separately for 1 hour at 870 °} C., then ground for 2 hours in a vibrating mill with double-distilled water and, after drying, mixed with a binder solution using polyethylene glycol. These separate mixtures are pressed into separate single toroidal cores having an outside diameter of about 5 mm, an inside diameter of about 3 mm and a core height of about 1 µm to a density of about 3 g / cm ^3. The compacts are each in separate ferrite filters with fitted covers in the compacts. refractive compositions used and n "·. ■■ · 7stündigem heating at 1300 ⁰ C initially <) 0, round in air and then sintered for 24 hours in lv .- 'sam flowing pure nitrogen with less al 1:02 volume percent oxygen. The sticky flow is around 0.4 l / h with an oven volume of ν «· .-! 1.5 1. The cooling from the sintering temperature hi> 600 ⁰ C is performed in 2 hours, from 600 down to? T'ü C in 3 hours and then slowly to room temperature.

in FIG. 3 is the. temperature-dependent permeability curve of the described ferrite core \ A and IA shown. The initial permeability is in a very large temperature range from -50 to; 105 "C more than 10,000 with a measuring field strength of // - 1.6 mOc and a measuring frequency of 5 kHz.

Example B.

A similar to that shown in FIG. 1 has the following compositions with respect to its individual cores, which are shown in FIG. 2 with the points XB and IB are shown. The composition XB is 52 mol percent Fe ₂ O _3, 29 mole percent of ZnO and 19 Molpro- ■ n nt MnO (Te = 55 ^J C), the composition of IB 52 mole percent Fe ₁ O _3. 22 mol percent ZnO and 26 mol percent MnO (Tc - = 130 ° C). The zinc content of the two individual cores IB and 2B therefore deviates more from one another than the zinc content of the individual cores IA and 2/4. The Eirazel kernels according to example b are produced in approximately the same way. However, a polyvinyl alcohol solution is used as the binder, and the dimensions are 14 mm outside diameter, 8 mm inside diameter and 4.4 mm core height. The pressing pressure is 3 t / cm ¹ , and the cooling from the sintering temperature to room temperature takes place slowly at about 100 ° C./h.

In FIG. 4 shows the temperature-dependent permeability curve of the core combination described in this example B. From this curve progression it can be seen that by choosing two individual cores with very different Curie temperatures at the lower Curie temperature, a not inconsiderable jump in the permeability curve occurs. However, it is guaranteed that the initial permeability of -10 to + 130 ⁰ C is more than about 10,000 and in a smaller operating temperature range of 30 -J; 25 ⁰ C sogai is more than 18,000. The measuring field strength in this example is N = 0.6 mOe, the measuring frequency 5 kHz,

Example C

According to this exemplary embodiment, the composition 1 C consists of 52 mol percent Fe ₈ O ₃ , 24 mol percent ZnO and 24 mol percent MnO (T _e = 115 ° C), the composition IC, as in Example A designated as 2A , of 53 mol percent Fe _a O _3, 26 mole percent of ZnO and 21 mole percent of MnO (T _c = 110 ⁰ C) (s. F ig. 2). Compared to example A, the core combination IC + IC has an overall lower ZnO content, and the Curie temperatures of the two individual cores are approximately the same. The position of the strongly pronounced secondary permeability maxima, the permeability-temperature curves of the individual cores, is very different (FIG. 5).

The Finzelringkernf (outer diameter approx 5 mm, inside diameter about 3 mm, core height about 1.5 mm) are in the same way as in Example A. manufactured.

From FIG. 6 shows the temperature-dependent permeability curve of the core combination given in the present example C. The μ (7> curve of the core combination is substantially equalized, so that no distinct secondary Permeabilitätsmaxima despite Hohei initial permeability of more than 8000 in a wide temperature range of -. Occur 50 to +115 ⁰ C more, since the two individual cores, as indicated above, approximately the same The permeability was measured at a measuring field strength of H = 1.6 mOe and a measuring frequency of 5 kHz.

The sintering time for the thick-walled 14 mm toroidal cores (Example B) as for the thin-walled 5 mm toroidal cores (Examples A and C) can be shortened considerably, when sintering takes place in furnaces with a vacuum device.

Claims (6)

Patent claims: 1. Ferromagnetic ferrite core with an initial permeability of more than μ _α = 5000 in a large operating temperature range of about 25 ± 75 ° C for broadband transformers, pulse transformers, power transformers or the like at high frequencies, which is composed of at least two individual cores with different zinc content , characterized in that the starting substances for the individual grains (1, 2) have less than 0.05 percent by weight of total impurities and are selected from the following range (5): 51.5 to 53.0 mole percent FeAi.
20 to 30 mole percent ZnO,
17.0 to 28.5 mole percent MnO. 2. Ferromagnetic ferrite core according to claim 1, characterized in that the starting substances are chosen for the individual cores such that dw individual cores (1, 2) their secondary and have tertiary permeability maxima at different temperatures. 3. Ferromagnetic ferrite core according to claim 2, characterized in that the starting substances for the individual nuclei are selected in such a way that that the individual cores (1, 2) have approximately the same Curie temperature. 4. Ferromagnetic ferrite core with high an "(angspermeabilität of more than about. ^ E = 10,000 at room temperature according to claim 2, characterized in that the starting composition of a single core (\ A) " about 52 mol percent S Fe ₁ O ₃ , 28 mol percent ZnO and 20 mole percent of MnO and the starting composition of the at its single core (IA) about 53 mole percent Fe ₁ O ,, 26 mole percent of ZnO and 21 mole percent of MnO having te 5. Ferfomagnetiseher ferrite core with high initial perfection ton more than about μ * = 10 000 at room temperature according to claim 3, characterized in that the starting composition of a single chain » (IB) about 52 mol percent« s Fe ₁ O ₃ , 29 mol percent ZnO and 19 mol percent MnO and the initial addition of the other single core (IB) has about 52 mol percent Fe ₁ O ₃ , 22 mol percent ZnO and 26 mol percent MnO. 6. Ferromagnetic ferrite core with a high initial permeability of more than about μ _α - 10 000 at room temperature T = 2O ⁰ C according to claim 1, characterized in that the starting system of one ßinzelkernes (IC) about 52 mol percent Fe ₁ O ₁ , 24 mol percent ZnO and 24 mol percent MnO ufld the initial joint session of the other small nucleus (IC = tA) 53 mole percent Fe ₁ On, 26 mole percent ZnO and 21 mole percent MnO. 1 sheet of drawings