DE1263852B - Magnetic core transformer with a coupling factor that can be changed by means of a control current - Google Patents

Description

Magnetic core transformer with a magnetic core transformer, whose Coupling factor in control current changeable coupling factor wide limits electronically can be regulated by a control current, variable direct current or current pulses, are very useful for many purposes, especially in communications engineering. she can, for example, be used as an electrically switchable transformer in Gate circuits for alternating current or pulse signals are used. You can also do it in electronic telephone switching technology for testing the call and Use the occupancy state of the subscriber lines, with the one to be determined Line current flows through the control coil of the transformer and thereby the connection the galvanically separated test signal. The latter can be made optionally a continuous alternating voltage or a voltage pulse. transmitter of the type mentioned can also serve as modulators, with the modulation the input voltage by changing the coupling between the input and output winding is effected. Furthermore, transmitters with an electrically controllable coupling factor can be used can basically also be used as a magnetic amplifier when the coupling factor could be regulated within sufficient limits and with a relatively small control power.

Most of these or other applications don't just use one The greatest possible change in the coupling factor is desired, but above all the possibility of a complete decoupling of the input and output windings and sufficient decoupling between these and the control winding.

It is already known in principle, the degree of coupling between two To change coils within certain limits by changing the permeability of the coupling, ferromagnetic core with the help of a special, pre-magnetizing winding changes, whereby the leakage inductance of the two windings is changed at the same time. However, these arrangements have the disadvantage, which is decisive for some applications, that a perfect coupling and above all a perfect decoupling between Input and output winding itself with the help of very large control currents is far from possible. They are also with an undesirably large change affected by the inductance of the transformer windings.

There are also magnetic amplitude modulators known in which the carrier signal is modulated by controllable inductors that are pre-magnetized by direct current (e.g. German patent specification 1050 839). That on the shape of the magnetization curve of the core material based blocking-conduction ratio of such inductors however not very satisfactory and the arrangements require additional transformers.

There are also arrangements known with the help of current-controlled Inductivities in complex circuits cause sensitive modulation or Enable signal transmission. They are, however, working with resonance voting therefore only usable for a certain carrier frequency and require a considerable one Circuit effort (German patent specification 910 671).

Finally, arrangements are also known in which the above plugged Objective is sought with the help of superconducting substances. This is where the coupling changed between two adjacent coils in that an intervening Sheet metal with the help of a controlling magnetic field from the superconducting state (complete magnetic shielding) to the normally conductive state (weaker shielding) is brought. However, this method has the disadvantage of being laborious and time-consuming Freezing (liquid helium) and also leads through the very narrow transition area practical difficulties between the two conductivity states.

The disadvantages of the known arrangements are caused by the magnetic core transformer avoided according to the invention. According to the invention, this is characterized by that the input and output windings - one with four symmetrically arranged Openings provided core penetrate through two openings so that when excited of the input winding, the associated total magnetic flux, the total winding area the output winding is not penetrated (coupling = 0), and that a control winding of all four core openings in such a way that two of the four are between the openings lying core zones (control webs) from the tax flow become saturated. can so that the flow of the input winding with the help of the control current can be forced to change its path of closure by the winding surface the output winding (coupling + 0).

The principle of the invention is based on Fi g. 1 emerged. The two to be linked Windings, the input winding E and the output winding A enforce the as cylindrical disc-shaped core K in two diametrically opposite one another cylindrical holes 1, 2 and 3, 4, with the centers of the holes in the core plane are arranged rhombically so that their connecting lines are perpendicular to each other and cut yourself in half. With the help of the controllable direct current IS in the control winding S, which consists of two series-connected partial windings S ″ and Sb and all four Holes in the direction of winding shown are penetrated by the four core webs, which separate the holes, the two lying diagonally surrounded by the control winding Bars that are shown hatched and referred to below as "control bars" are magnetically saturated to a variable extent at their narrowest point. One sees easily one that in the arrangement shown without the bias through the control current, d. H. at IS = 0, the magnetic coupling between the input winding E and the output winding A is zero for reasons of symmetry and that if present of the control current at the beginning of saturation of the control webs and corresponding - Increase in their magnetic resistance generated by the input winding E. Flow according to the dashed lines in increasing measure to the other, not dodges saturated webs and thereby the winding area of the output winding A. interspersed. Magnetic coupling occurs when the control bars are completely saturated between the input and output winding almost its full value 1.

In the arrangement according to FIG. 1 there is still an undesirable coupling between the control circuit and the transmission circuits. In further training of the Invention, this deficiency can be remedied by having two identical arrangements of the kind described interconnects. that those of the transference circles voltages coupled into the control winding and vice versa are compensated, z. B. by opposing series connection of the two control windings. Here you can the two transformer cores provided with their control windings, for example are also close to each other and shared by the input and output windings be embraced.

The shape of the core can vary from that of FIGS. 1 differ largely. . As in Fig. 2, one can, for example, the holes or openings give the core a sector shape; those for blocking the control webs by saturation is cheaper.

Also, the core can be made from several parts in the interest of easier production and winding, in particular for the purpose of using slide-on bobbins, which, for. B. with. finely ground joints or by nesting transfer plates. An exemplary embodiment for this is shown in FIGS. 3 and 4 shown. It is a cuboid core that is shown in FIG. 3 in side view with windings drawn in vertical cross section and in FIG. 4 in a view from above with a partially shown horizontal cross section. The core consists of four sub-cores Ki, K2,: K3 and K4 lying next to one another with ground parting surfaces, of which the two inner sub-cores K2 and K3 are designed as E-cores and the two outer sub-cores K1 and K4 as U-cores. In the four window openings 1, 2, 3 and 4, the windings already applied to the bobbins are accommodated. The assembly takes place in such a way that the E cores K2 and K3 are pushed laterally into the coil formers carrying the windings A and S ″, after which the coil former carrying the windings E and Sb is pushed from above or below over these E cores and that the U-cores K1 and K4 are pushed laterally over this bobbin and the E-cores.

It should be noted that the two series-connected partial windings S ″ and Sb of the control winding are assigned to the core openings in a different way are as in the F i g.1 and 2. However, if one considers the current directions of these partial windings when comparing the penetration of the various openings, one recognizes that the effect the control windings is the same in both cases.

The magnetic core transformer according to the invention can on the one hand be switched through Transformers can be used for gate circuits, but above this it can be advantageous also for amplitude modulation, for magnetic amplification and for measuring Streams are used. Its use is not restricted to AC signals only limited, but also with pulse-shaped signals to be transmitted and / or pulse-shaped Control signals possible.

The relationship between the coupling factor and the control current depends on the magnetization curve of the core material and on the size and the course of the core cross-section along the control webs and therefore in general non-linear. In the case of switchable transformers, this is not a disadvantage. here all that matters is a sharp increase in the coupling with the control current, what due to a core material with a steep magnetization loop and low remanence and coercive field strength can be achieved and through control webs, their cross-section so small. than the alternating current or pulse power to be transmitted allows. When used for modulation purposes, the connection between control flow and coupling factor through the choice of a suitable core material and an appropriate one The shape of the control webs between the holes is linearized to a certain extent or can be approximated to another desired function: by means of an additional The operating point of the modulator can also be set favorably in the premagnetization will.

Depending on the level of the frequencies to be transmitted or the shape of the pulses to be transmitted and depending on the size of the available control power and The core can be made from transfer plates layered or made of soft magnetic ferrite materials. Ferrites with low saturation induction and high permeability are particularly advantageous if the control power is very small with a small power to be transmitted target, such as B. in modulators or magnetic amplifiers. They also allow the Transmission or modulation of high frequencies.

F i g. 5 shows the on a controllable transformer according to the invention with a transmission ratio of 1: 1 at a frequency of 100 kHz and a load output voltage UA measured by 150 SL depending on the control flow 0s. This transformer, which is only a demonstration example and not optimal is dimensioned, corresponds to FIG. 1 in terms of core shape and windings. 1, where the decoupling between control and transfer windings in the one described above Way was achieved by using two identical cores. The two cores exist made of highly permeable ferrite plates with the following dimensions: outer diameter 45 mm, thickness 3 mm, hole diameter 11 mm, smallest control land width 2 mm. The transfer windings E and A consist of 15 turns each, which are wound together over both cores, the control windings S consist of 4 - 50 turns, which are wound on both cores separately are. F i g. 5 shows the considerable variation in output voltage that with an increase in the control flow 0s from very small values to almost the full value of the input voltage U "rises. The approximation of the output voltage 0 in the decoupled state is practically only due to asymmetries in the position of the core openings and limited by capacitive coupling between the transformer windings. These Influences, however, have nothing to do with the principle of the invention and can be press down very far.

Claims (11)

Claims: 1. Magnetic core transformer with a means of control current changeable coupling factor, characterized by the fact that the input and the Output winding has a core provided with four symmetrically arranged openings penetrate through two openings (1, 2 or 3, 4) so that when the input winding is excited (E) the associated total magnetic flux the total turn areas of the output winding (A) not penetrated (coupling = 0), and that one control winding every four core openings passes through in such a sense that two of the four lie between the openings Core zones (control webs) can be saturated by the control flow, so that the flow of the input winding (E) can be forced with the help of the control current, its closing path to a variable extent through the winding area of the output winding (A) to take (coupling + 0). 2. Transformer according to claim 1, characterized in that that the centers of the core openings (1, 2, 3, 4) for the input and output winding are arranged rhombically in the core plane and that of those between adjacent Openings (1, 4 and 2, 3) lying, narrowed control webs two diagonally opposite one another opposite are used for flow control. 3. Transformer according to claim 1 and 2 with particularly high control sensitivity, characterized in that the narrowest cross-sections of the control webs lying between the core openings so small are considered to be the greatest power to be transmitted, taking into account the saturation magnetization of the core, just enough. 4. Transformer after Claims 1 to 3, characterized in that the relationship between the degree of coupling and control current through the course of the control bar cross-section as a function of the web length and / or the shape of the magnetization curve of the core material is adapted to the intended use. 5. Transmitter according to claim 1 to 4, especially for small powers to be transmitted and with high control sensitivity, characterized in that highly permeable core materials with low saturation induction, in particular ferrites can be used. 6. Transmitter according to claim 1 to 5, characterized characterized in that the core consists of several parts (K1, K2, K3, K4) with finely ground Joints are composed or nested together from transfer plates. 7. transformer, characterized in that two identical transformers according to claim 1 to 6 are interconnected in such a way that the between the control circuits and Compensate for voltages coupling over the transformer circuits. B. Transformer according to claim 7, characterized in that the transfer windings (E, A) both Wrap cores together, while the control windings (S) on both cores are separated are wound up. 9. Use of transformers according to claim 1 to 8 for amplitude modulation. 10. Use of transformers according to claim 1 to 8 for magnetic amplification of signals. 11. Use of transmitters according to claim 1 to 8 for measuring Stream.