DE1016380B - Inductance controllable by pre-magnetization - Google Patents

Description

Inductance controllable by premagnetization The invention relates to on a controllable inductance, consisting of one between the poles of one Electromagnet attached coil on a closed ferromagnetic core au.s sintered material, which consists of two yoke parts and at least two of the coil windings supporting legs is composed and its permeability by a change the strength of the bias field generated by the electromagnet changed can be. Such facilities can e.g. B. in controllable oscillation circles until. at frequencies of about 10 1 Hz, but also in magnetic amplifiers, ticker circuits (Flip-flop circuits), etc. can be applied. The coil is usually in, series connected with a fixed alternating current resistance and with an alternating current source connected, and the current flowing through the alternating current resistance is through the Amperage controlled in the electromagnet.

To the; required to generate the pre-magnetizing field To keep electrical energy within reasonable limits, the dimensions must of the coil core should be as small as possible, especially at high frequencies of the Coil of current flowing through it.

The very small coil dimensions required, however, make the Manufacture and the composition of the coil core and the winding especially difficult. The invention aims to provide a type which can overcome these difficulties eliminated if possible.

The inductance according to the invention is characterized in that the yoke parts of the between. the poles of an electromagnet: attached ferromagnetic Coil core through. one or more supports made of magnetically non-conductive material are firmly connected and that the. Core legs carrying windings with ground surfaces on the sides of the yoke parts that are also ground are attached closely.

It should be mentioned that controllable inductances, which come from between the Poles of an electromagnet attached to a closed fer romagnetic coils Core made of sintered material, e.g. B. made of ferrite, are already known. It is also known such coil cores from two yoke parts and several of Windings surrounded core rods, which are arranged between these yokes, assemble. In these known arrangements, however, the core bars of the windings have one considerable cross-section, so @ that a high control energy to generate a sufficiently large bias field is required. In the case of inductance According to the invention, the core legs can have a much smaller cross section have, whereby the required bias field can remain low. the end For this reason, the core for the electromagnet can also be kept small. aside from that the inductance according to the invention still has the advantage that the individual parts can be easily assembled and that the core assembly also in use thin core leg is very stable.

The invention is explained in more detail with reference to the drawing, in which the FIGS. 1 and 2 show an exemplary embodiment in longitudinal section and in cross section and FIGS. 3 and 4 show a second exemplary embodiment in the same manner of representation demonstrate.

The device shown in Figs. 1 and 2 consists of one Electromagnet with an essentially cup-shaped core, like the one used for premagnetization of coil cores is known per se. The core of the electromagnet consists of one Ring 1, two lids 3 and 5 that fit on it and two centrally arranged core parts 9 and 11 made of electrically poorly conductive, sintered ferromagnetic material, z. B. from cubic crystallized ferrite. In that of these. Share educated The field winding 7 is housed in the closed pot. The annular parts 9 and 11 simultaneously form the yoke parts of the closed coil core. they are at the ends of a tubular., running in the axis of the pot core Carrying organ 13 made of magnetically non-conductive material, e.g. B. Glass, attached and on two opposite Sides ground flat parallel to the axis of the carrier 13; two of these to different ones Areas belonging to the yoke parts lie in the same plane and are divided by two flat ones Chopsticks 15 and 17 made of electric. poorly conductive, sintered ferromagnetic Material connected to one another, which is also ground at least at the ends Have surfaces with which they are ground to the mentioned; Faces of the rings .9 and 11 are attached. The rings 9 and 11 form in this way the rods. 15 and, 17 have a closed ferromagnetic core for the Windings 19 and 21 attached to the rod cores.

These windings can be connected in series and constitute one Inductance, the value of which is regulated by the premagnetization of the core rods 15 and 17 can be. The Vorrnagnetisierung is by means of the coil winding 7 and of the core 1, 3, 5, 9, 11 interacting with it. That from a stream The bias field generated in the winding is in the two core bars 15 and 17 spatially rectified, while the coil parts 19 and 21 are so rearranged in one another are that the field generated by these alternating current-carrying windings eT in the two core rods is spatially opposite, so that the two formed by the winding 7 on the one hand and the windings 19 and 21 on the other hand Coil systems are not coupled to one another. If through the 'coils 19 and' 21 z. B. a high-frequency current flows, so the occurring at the ends of these coils Voltage can be changed by changes in the current flowing through the coil 7.

To reduce the control energy required for the field winding 7 It is essential that the core rods 15 and 17 have a very low Cross section of z. B. 0.3 to 1 mang have. This is the case with the type of construction described Easily accessible because the rods 15 and 17 are made as individual parts, in a simple manner Way sanded with a flat grinding wheel and after applying that Windings 19 and 21 on the one consisting of the support member 13 and the rings 9 and 11 Structure, e.g. B. by gluing, can be attached. The one obtained in this way The structure is proportionate despite the brittleness of the very thin core rods 15 and 17 resistant and easy to handle during production, since the parts 9. 11, 13 result in a rigid structure in which the support member 13 is a "backbone" as it were represents. This structure is first made by gluing the yoke rings 9 and 11 to the support member 13 made, with the most accurate possible adaptation of the length of the Structure to the distance between the bottom and top of the lid 3 or 5 can be achieved that before the hardening of the adhesive between the Rings 9 and 1i an elastic pressure member, for. B. a compression spring is attached, whereupon the structure is left in the pot 1, 3, 5 until the adhesive has hardened. The structure 9, 11, 13 is then removed from the pot; on a flat Grindstone are ground on the flat surfaces (see Fig. 2), whereupon the core rods 15 and 17 with the windings 19 and 21 are glued to them. As shown in Fig. 1, the length of the rods 15 and 17 is not critical, provided that that the rods are slightly shorter than the inner height of the pot 1, 3, 5. The contact areas between the rods 15, 17 and the rings 9, 11 are relatively large, so that the air gaps between the rods and rings only slightly increase the magnetic resistance of the closed one formed by the rods and rings Induce magnetic circuit.

Also the mating surfaces between the ring 1, the covers 3 and 5 and the Rings 9 and 11 are preferably ground, so that also those between them Share existing air gaps only minor obstacles to the bias field the coil 7 represent. The core rods 15 and 17 can, if desired, under mechanical Tensile or compressive stress are attached to the structure 9, 11, 13, for. B. in the way, that a material is selected for the support member 13, the coefficient of expansion from that of the rods 15 and 17 differs significantly, and that drying of the adhesive take place at a high temperature. leaves. The mechanical tension is known to cause a change in the course of the magnetization characteristic, so that a favorable course for certain purposes can be achieved *. It is, however known such mechanical stresses, due to parallel to the ferromagnetic Core components arranged support body made of magnetically non-conductive material to achieve that are firmly connected to the ferromagnetic core parts.

If, in addition to the variable bias, there is a permanent bias of the coil core is desired, a rod-shaped permanent magnet in the support member 13 23 are attached, e.g. B. from a ceramic permanent magnetic material low permeability; the latter in order to avoid that the magnet 23 is a magnetic Represents short circuit of the core rods 15 and 17. Let it be for this. still noticed it is known per se, the magnetizing field in a controllable inductance to be generated in that in addition to the electromagnet, a permanent magnet on the with a Core provided coil acts.

3 and 4 show a second embodiment in which to Place of the rings 9 and 11 semicircular ferromagnetic yoke pieces 25 and 27 are used whose facing straight sides are flat. are ground and the core rods - which in this case must be ground plane-parallel - between. to lock myself in. The yoke pieces 25 and 27 are supported by supports 29, the z. B. are made of porcelain. A sufficiently precise fit in pot 1, 3, 5 can be achieved that the whole, from the previously with the necessary Mating surfaces provided parts 15, 17, 27, 29 existing structures in an assembly jig is glued together.

Claims (7)

PATENT CLAIMS: 1. Controllable inductance, consisting of a between the poles, an electromagnet attached to a closed ferromagnetic coil Core made of sintered material, which consists of two yoke parts and at least two of the coil windings supporting legs is composed, characterized in that the yoke parts (9, 11 or 25, 27) by one or more supports (13 or 29) made of magnetic non-conductive material are firmly connected to each other and that the windings (19, 21) supporting core legs (15, 17) with ground surfaces on the side as well ground surfaces of the yoke parts are attached adjacent. 2. Controllable inductance according to claim 1, wherein the ferromagnetic core of the electromagnet in the essentially pot-shaped with two core parts axially arranged in the interior of the pot (9 and 11) and the coil (19, 21) between these two core parts is attached, characterized in that the two axially arranged parts of the pot core simultaneously form the yoke parts of the closed coil core, through a rod-shaped or tubular shape running in the axis of the pot core Carriers (13) made of magnetically non-conductive material are firmly connected to one another. 3. Controllable inductance according to. Claim 2, characterized in that the yoke parts (25, 27) of the closed coil core by two rods (29) made of magnetically non-conductive Material are connected, which run parallel to the axis of the pot core. 4. Controllable inductance according to claim 2 or 3, characterized in that each yoke part (9, 11) of the coil core. two opposite sides is ground flat parallel to the axis of the carrier and two of these surfaces belonging to different yoke parts and lying in one plane are connected by a rod core (15b: between 17) carrying a winding (19 or 21). 5. Controllable inductance according to claim 3, characterized in that the yoke parts of the coil core from There are two semi-cylindrical disks (25, 27) each, whose parallel to the cylinder axis Running flat surfaces ground flat and parallel to each other with little Interstices are arranged, with the resulting between these surfaces Slit the rod cores connecting the yoke parts and carrying the winding (15, 17) are attached. 6. Controllable. Inductance according to claim 2, characterized in that that the carrier (13) is tubular and in the interior of the carrier a rod-shaped Permanent magnet (23) made of a material with low permeability and high remanence is appropriate. 7. Controllable inductance according to one of the preceding claims, characterized in that the yoke parts (9, 11 or 25, 27) verb: indenden Rod cores (15, 17) under mechanical tension on the one from the carrier (13 or 29) and existing structures are attached to the yoke parts. Considered publications: German Patent Nos. 583 493, 587 390, 659138, 814178; Swiss patent specification No. 203,786; Becker-Döring, "Ferromagnetismus", 1939, pp. 103, 104; »Funk und Ton«, H. 11, 1950, pp. 559 to 568; "Erz", H. 21, 1951, p. 643; "Radio Mentor", issue 11, 1952, P. 531.