DE445824C - Device for damping electrical shock waves by connecting two wave feeds against each other - Google Patents

Description

It is known, in receiving systems for high frequency, the interference from electrical shock waves to be eliminated by switching two wave trains against each other. the Both wave trains run through oscillation circles with slightly different coordination, see above that the receiving system including the antenna has two natural frequencies. the The suppression of interference is based on the fact that the shock waves have both natural frequencies equal excite strongly, while the incoming signals are only tuned to the one frequency are. These known devices work imperfectly because it often happens that from for any coincidental reasons also by shock waves the one frequency stronger to the response comes as the other. Then they are as good as not suppressed in the receiving device. The second number of vibrations, who owns the system are detrimental to the fact that other stations happen to be work with this second frequency. The invention therefore aims at the shock waves can be effectively suppressed in a system with only a single frequency.

This is achieved in that two wave trains are switched against each other, from one of which has two or more oscillation circles for the purpose of weakening the shock waves with ohmic coupling, while in the other wave train a larger one Amount of energy of the shock waves is maintained. Let us now leave the two wave trains act on the receiving apparatus against each other in such a way that the shock waves occurring in them cancel each other out, so the signal waves do not cancel each other out because that The ratio of their amplitudes is different. The second wave train in which the shock waves are not dampened by special means, need no oscillation circles at all to go through. However, to be sure that

*) The patent seeker stated as the inventor:

Dr. Hans Riegger in Berlin-Pankow.

44S 8H

the in. It recommends that the receiving apparatus have waves acting against each other in the same phase to send the second wave train through the same number of oscillation circles as the first, with this second series of oscillation circuits, however, the ohmic coupling is missing.

It is known that the shock waves are dampened more strongly than the continuous oscillations in two oscillation circuits with ohmic coupling. In Fig. Ι two such oscillation circles are drawn. The windings i, which are traversed by incoming electrical waves, act as a transformer on windings 2. These form an oscillating circuit with the capacitor 6, while the windings 3 and the capacitor 7 form a second oscillating circuit. Both oscillating circuits are coupled by an ohmic resistance w. As long as there are only standing waves in the two oscillation circles, almost no current flows through the resistor. In the case of oscillation processes, on the other hand, which only consist of an increase in energy and a decay, a larger part of the electrical energy takes its way through the ohmic resistance w and is destroyed in it. While continuous waves lose only a small part of their energy in w , the shock waves here give off a considerable amount of energy. Fig. 2 shows a corresponding embodiment with three oscillating circuits, which are coupled to one another by the ohmic resistors W ₁ and w _z. The oscillation circuit inserted in the middle consists of the capacitance 8 and the self-induction 9.

According to the invention now acts a wave train, the such oscillation circuits with ohmic Coupling has gone through a wave train, in which kernels special means for Reduction of the energy of shock waves are applied. The circuit of such a Device according to the invention is shown in Fig. 3. The incoming wave trains are from recorded the turns 11 and passed on to the turns 2 and 13 by means of a transformer. The turns 2 form part of the same in the oscillation circles, which are shown in Fig. 1 are shown. The turns 13, however, form with the capacitors 14 and 15 and the windings 16 two further oscillation circles, which, however, by a self-induction 17 are coupled to each other. In these two oscillation circles there is a lack of an ohmic Resistance does not dampen the shock waves instead. The of the turns 16 in the Currents generated by turns 23 therefore contain a greater percentage of shock waves than the currents generated by the windings 3 in the windings 22. The turns 22 and 23 are connected against each other and are dimensioned in such a way that the shock waves occurring in them just cancel each other out. Since the continuous signal waves but in other If there are strength ratios, they do not cancel each other out, but become in the receiving apparatus 20 perceptible. The ones consisting of 13, 14, 15 and 16 Both oscillating circuits have the purpose of larger phase shifts in this circuit between the waves in the windings 23 and those in the windings 22 to prevent, otherwise the mutual cancellation would be less perfect.

To also lower phase shifts between the mutually acting wave trains To be able to eliminate, a circuit according to Fig. 4 is used. She makes a difference differs from the one according to Fig. 3 only through the inclusion of the aperiodic one, which is known per se Oscillation circuit 25, 26 between the turns 16 and 23 by means of the adjustable Capacitance 26 can be adjusted to phase equality in 22 and 23.

The mutual cancellation of the shock waves can also be independent of the phase of the Achieve vibrations, e.g. B. with a circuit according to Fig. 5. The waves are through the Detectors 20 and 21 initially rectified, and only the resulting low-frequency go Currents are switched against each other by means of the windings 22 and 23, so that their Difference in the measuring apparatus or telephone 24 is perceptible.

Claims (3)

Patent claims: 1. Device for attenuating electrical shock waves by connecting them against each other two wave trains, characterized in that the one wave train for the purpose of suppressing shock waves or two runs through several oscillation circles with ohmic coupling, while in the other wave train a larger amount of energy the Shock waves are sustained. 2. Device according to claim 1, characterized in that the other wave train passes through the same number of oscillation circuits, but without an ohmic coupling own. 3. Device according to claim 1, characterized by the interposition of an aperiodic oscillation circuit with adjustable capacitance (26), by means of which the two wave trains can be adjusted to phase equality. _; 1 sheet of drawings.