DE935799C - Arrangement for magnetic demodulation - Google Patents

Description

ISSUED DECEMBER 1, 1955

P 9421 Villa j 2ia ^l

It is well known that the dependence is non-linear the magnetic induction of the field strength when using ferromagnetic! Substances as core material for magnetic demodulation of amplitude-modulated oscillations.

The explanation of the mode of operation of such demodulators should be based on the drawings. In Fig. 1 the idealized course of the magnetization characteristic S = / ″ (H) of the core material is shown. B denotes the magnetic induction and H the magnetic field strength. In this diagram, the hysteresis phenomena are neglected. The increase in the saturation area is also not taken into account .

The demodulation process can be implemented in the simplest form, for example with the aid of the basic circuit shown in FIG. Be located on a ferromagnetic core K with that in Fig ι illustrated magnetization curve following windings which are shown separately for clarity. The primary winding P, which is supplied to be demodulated high frequency vibration, the winding M for generating a magnetic bias by direct current from the power source G and the winding D, in which the demodulated voltage is induced, which in turn generates the low-frequency and modulation current I cos ωί after eliminating the high-frequency component with the help of known filter means, for example the choke coils 52, through which the consumer resistance Ri is flowed. Here, ω represents the angular frequency of the low-frequency modulation oscillation.

The high-frequency current supplied to the winding P is kept sinusoidal by the choke coils Si. The magnetization current in the winding M sets the field strength H _{0 of} the premagnetization with the aid of the variable resistor Rz so that the operating point A coincides approximately with the break point of the magnetization curve, as shown in FIG. 4, which corresponds to FIG. is shown. Then the arrangement works analogously to a current rectifier, with the only difference that instead of the current, the alternating induction flux Φ, as shown in FIG. 4, is rectified. In the first case a non-linear current-voltage characteristic is used for demodulation, in the second case the non-linear field strength induction (or current-flow) characteristic is used.

The high-frequency carrier current in the winding P (Fig. 2), which is indicated in Fig. 1 by an oscillation period, generates an alternating magnetic field,

ao, which is superimposed on that of the coil M (Fig. 2) generated constant flux _Φ ο.

As can be easily seen, the upper (right) half-waves of the current cause! and thus the corresponding changes in the field strength H do not change the size of the induction B, because saturation already exists in this working area with the proposed and illustrated selection of the working point A. The left (lower) half-waves of J, on the other hand, cause a likewise semi-sinusoidal change in the induction B and thus in the flux Φ (in the case of the idealized characteristic curve shown), the course of which is shown in FIG. 1 as a function of time t. These negative half-waves are superimposed on the constant ₀ generated by H and B ₀ corresponding saturation flux _Φ ο, which is the sake of clarity in Fig. Ι in such a scale applied such that the ordinate _Φ ο the ordinate B ₀ is the same. A scale is also assumed for J in which, for the arrangement considered here, changes "in I and H in the representation correspond to one another in terms of size.

The arrangement shown in principle, known in principle, thus corresponds to a half-wave rectifier arrangement.

Using two inductors for demodulation results in a push-pull arrangement. An embodiment is known in which the chokes used for demodulation are both from the rectified as well as being traversed by the high frequency nut. This occurs in the input circuit of the Demodulator on additional losses, which significantly reduce the efficiency of the arrangement.

According to the invention, therefore, in an arrangement for 'magnetic demodulation by means of two or several magnetic circuits proposed, the circles modulated by a suitable arrangement of the To couple high frequency and the demodulated voltage leading windings so that the immediate The effects of the modulated high-frequency flows in the demodulation branch cancel each other out. An arrangement according to the invention exists, for example made of two separate magnetic cores that carry a high-frequency winding and are placed on top of one another are that they are enclosed together by the demodulation winding.

A particularly advantageous arrangement results from the use of a three-legged core, on its outer legs the primary, high-frequency leading windings in push-pull circuit are arranged, while the demodulation winding is housed on the middle leg. Through this occurs in the middle leg in addition to the constant flux required for magnetic biasing only the demodulated induction flux. The input circuit is therefore not additionally attenuated as of course also with a corresponding arrangement on separate cores, if the middle one Leg has a high magnetic or electrical resistance.

The use of a three-legged core is known for the amplitude modulation, on the middle leg of which the high-frequency winding is arranged. In addition to the resistance of the middle limb, the high-frequency flux also finds the magnetic resistance of the ^8s outer limb. This dampens the high-frequency circuit even if only part of the core has a high magnetic or electrical resistance.

In Fig. 3, a three-legged core is shown as an example of the arrangement according to the invention.

The modulated oscillation is applied between terminals A and B. The windings of the legs 1 and 3 are connected in such a way that the primary induction flux closes via the legs 1 and 3 of the core in the absence of the premagnetization without the flux flowing through the leg 2. The field of the premagnetization, which is generated by the winding on the leg 2, runs in the legs 1 and 3 in opposite directions. Is the. Working point by setting the premagnetization again at the break point of the characteristic, one half-wave of the high-frequency oscillation will cause a change in flux in leg 2 through the action of winding r, while the other half-wave will cause a corresponding change in flux in leg 2 through the action of winding 3. In this arrangement, both half-waves of the high-frequency current are used.

This process can be seen from FIG. 4, which can be easily understood when compared with FIG. The characteristics of the two magnetic circuits are labeled Li and L 2. In each case the upper (right) half-wave of the current I is rectified by the action of the characteristic curve Z, 2 and the lower half-wave in each case by the action of the characteristic curve Li. As mentioned above, the demodulated induction flux passes through leg 2 (Fig. 3) and induces the demodulated low-frequency voltage in the winding of this leg.

According to the invention, steel and iron types prove to be particularly advantageous as core material, which show a sharp kink in the magnetization curve even at low field strengths, the core being divided by lamination

is. Ferrites or similar non-metallic substances are expediently used for high frequencies with low conductivity and the mentioned magnetic properties.

In the arrangement according to FIG. 3, a winding is used both for generating the premagnetization and also to extract the demodulated oscillation. The generation of the bias would of course have can also be effected by a separate winding (as in FIG. 2).

Permanent magnets can of course also be used to achieve the premagnetization. This has the advantage of great stability and independence from hysteresis phenomena.

If there are several magnetic circuits, the permanent magnet is expediently arranged where the effects of the primary induction fluxes cancel each other out. In the example shown in FIG So the permanent magnet would take the place of the

zo leg 2 must take. Since this permanent magnet is traversed by an induction flux with twice the primary frequency, it is advantageous according to the invention to manufacture it from a ferromagnetic, poorly conductive material.

Claims (9)

Patent claims: i. Arrangement for magnetic demodulation of amplitude-modulated oscillations by means of two or more magnetic circles, characterized in that the circles by suitable Arrangement of the windings carrying the modulated high frequency and the demodulated voltage are coupled on separate or a common multi-legged core in such a way that the direct effects of the modulated induction fluxes in the demodulation branch are mutually exclusive lift. 2. Arrangement according to claim 1, characterized in that that the windings of the modulated high-frequency fluxes in a push-pull arrangement on the outer legs of a three-legged core are arranged, the middle leg of which carries the demodulation winding. 3. Arrangement according to claim 1, characterized in that that the high-frequency windings are arranged on separate cores that are common are enclosed by the demodulation winding. 4. Arrangement according to claim 1 and 2 or 1 and 3, characterized in that ferromagnetic materials are used as core material, which have a low electrical conductivity and a very pronounced one even at low field strengths Show saturation. 5. Arrangement according to claim 1 and one or more of claims 2 to 4, characterized in that that the nuclei are pre-magnetized by a constant field almost to saturation will. 6. Arrangement according to claim 1 and one or more of claims 2 to 5, characterized in that that the working point is placed approximately at the inflection point of the magnetization curve. 7. Arrangement according to claim 1 and one or more of claims 2 to 6, characterized in that that ferrites are used as ferromagnetic substances for the cores. 8. Arrangement according to claim 1 and one or more of claims 2 to 7, characterized in that that the premagnetization is effected by a permanent magnet. 9. Arrangement "according to claim 1 and one or more of claims 2 to 8, characterized in that that the permanent magnet lies in the magnetic demodulation circuit and is made of a ferromagnetic substance of little electrical conductance exists. Referred publications:
French patents nos. 635 173, 501 431. 1 sheet of drawings 1509585 11.55