SU42A1 - Device for amplifying microphone current using self-induction - Google Patents

Description

The device aims to enhance the microphone current by applying self-induction, which is modified according to the Alexander Alexander principle, which means that an additional winding is applied to the cores with self-induction, by changing the direct current strength in which we change the magnetic saturation of the cores. A general scheme of the device is shown in FIG. 1, with the letters designating: g - high frequency generator; P-antenna; 3-ground; L-self-induction; The magnetic circuit of the Alexandersensen magnetic amplifier, consisting of 4 cores.

The self-induction winding L consists of two coils wound on each of the two internal cores of the Alexander Asensen magnetic amplifier in such a direction that the magnetic flux F formed by this winding closes along the curve indicated in FIG. 1 dotted line; winding F, consisting of one coil, spanning both inner cores and powered by battery B through resistance r, serves to change the magnetic saturation of the flux circuit F; the value of self-induction is L

Alexandersen so that the circuit consisting of the capacitance formed by the antenna and the self-induction L is tuned to resonance; By changing the value of self-induction L and violation, thus, tuning, it is possible to achieve significant changes in the effective value of the current in the antenna; changes in self-induction L in FIG. 1 is achieved by varying the magnitude of the direct current / feeding the coil F; indeed, by changing the value of /, we thereby changing the magnitude of the magnetic flux Φ formed by the coil F (Fig. 1), thereby changing the magnetic saturation of the flux circuit Φ, and accordingly the magnitude of the self-induction of the coils Z ,.

The above-described Alexandersen circuit can also be adapted to amplify telephone frequency currents when telephoning over long distances, including two current rectifiers in the electrical circuit.

FIG. Figure 2 shows such an instrument connection diagram at a telephone exchange with current rectifiers. In this FIG. Letters designate: g - high frequency current generator (not

below about 20,000 periods per second); A - 2 - two current rectifiers; T-transformer with three windings W, Wz and R - S linear telephone wires; C-capacitor; The N-simplified image of the magnetic circuit of the Alexandersensen amplifier shown in FIG. 1 fully; L self-induction coil connected to high frequency circuit; / DC winding; B - battery; M-microphone

Shown in FIG. 2, capacitance C must be chosen in such a way that at a given generator frequency g and a given amount of self-induction L, the circuit consisting of C and Z, is tuned almost (but not quite) into resonance; then, as seen from the resonance curve in FIG. 3, with an increase in the value of self-induction L, for example, by the value of D /. the effective value of the current from / to / i changes and decreasing L by the value of D 2 current / decreases to, for example, / 2. The above changes of self-induction L are achieved by changing the DC current r in the coil F of the Alexandersersen amplifier (Fig. 2) ; The latter changes in the current / coil size F are caused by the fluctuation of the microphone resistance M caused, in turn, by the oscillation of the microphone membrane during the transmission of human speech. The fluctuations in the magnitude of the current amplitude I flowing in the circuit of capacitance C, caused by oscillations of the microphone membrane, will have approximately the form shown in FIG. 4. However, high frequency currents, as is known, do not act on a conventional type of telephone electromagnetic receiver (since the iron membrane of the receiver does not have time to follow the changes in the high frequency current); in order to circumvent the above difficulty, it is possible to apply, as shown in FIG. 2, two current rectifiers A and A and a transformer with three windings W / 1, Жз and Wj at the same time the windings of the transformer W and W must be connected so that the directions of the amperages formed by the windings when the rectified currents flow through them sent to one

the same side; If the latter condition is observed, the curve for the change of the ampere-lengths formed by the coils W and 2 will have approximately the form shown in FIG. 5 (solid line), and the iron membrane of the telephone of the receiving station will follow all the changes in the amplitude of the Ampere-Tube curves as if the curve of the telephone current in the linear wires changed according to the dotted curve shown in FIG. 5. Since the current strength / (Fig. 2) and the amplitude fluctuations of this current can be made significantly greater than the fluctuation of the current magnitude, the power of the currents transmitted to the line by means of the transformer T will have to increase significantly; thus, the range of the telephone transmission will have to be increased. Therefore, according to FIG. 2, a voltage resonance occurs, since capacitance C in this case is connected in series with self-induction L.

Another possible scheme is that in which capacity C and self-induction L are connected in parallel, as shown in FIG. 6 (designations in this fig. Are the same as in fig. 2); under the scheme of FIG. 6, capacitance C and self-induction L are taken such that, with a fixed membrane of the microphone M, the electrical circuit C-L is almost tuned to the resonance of the currents; in such a case, changes in a relatively small microphone current i would have to cause corresponding changes in the current amplitude of a significant force /, as in the case of the circuit of FIG. 2

SUBJECT OF INVENTION.

A device for amplifying a microphone current using self-induction, which is changed by changing the DC power, which influences the magnetic saturation of its core (according to the Alexandersensen amplifier principle) - characterized by the fact that the microphone M is introduced into the DC circuit, which influences the self-induction L, which is included in the high-frequency generator circuit, in series with capacitance C, with two parallel-connected rectifiers A, A-, li with two primary windings Wi and W-2 of transformer T, connected to rectifiers AI and A in such a way that the amperages formed by these windings are everywhere directed in the same direction, and the permanents of the indicated circuit are chosen so that it is tuned almost to the voltage resonance with the fixed membrane of the microphone.