DE436070C - Facility for high-frequency power lines occupied by high-frequency traffic - Google Patents

Description

The invention relates to a power line that is used simultaneously with the telephone or high-frequency telegraphic traffic is used. The task of this traffic to be maintained over the line even if by pulling a circuit breaker the line for heavy current traffic is interrupted, has been solved so far in such a way that in front of and behind the disconnector one bridge each, permeable to high frequencies, was laid in the line, the one or two small capacitors blocking the high voltage junction and a coil lying in series with it. The coils on both bridges were inductive coupled. This arrangement suffers from the fact that because of the necessary smallness of the Coils whose self-induction magnitude at a given frequency is determined by the capacitance of the small capacitors is determined, the coupling of the coils is not tightened sufficiently can be, so that each such separation point an attenuation for high-frequency transmission represents.

Another arrangement that is free from this disadvantage does not involve a bridge in the Line laid, but only each of the two through the pulled disconnector in the two Branch lines caused gaps through a capacitor coil system like the one above is described, bridged. The disadvantage here is that one at the separation point self-located intercom of the high-frequency traffic special coupling devices for their connection with the line requires that - unlike in the first mentioned Case - the bypass coil itself cannot be used for coupling when the circuit breaker is closed, because this short-circuits the mentioned coil in the closed position.

According to the invention, the two bridges, which are still from one Condenser coil system of the type described above exist, inserted into the line in such a way that that they form a line crossing for high-frequency traffic. You will consequently by closing the switch not short-circuited and can be used continuously to couple the intercom, and on the other hand, they do not bring any damping into the when the switch is open (pulled) Line for the high frequency into it. Both systems form when the switch is closed two parallel bridges in the line that toggled when the switch is opened be that each arrives in series in a line branch. This switchover takes place automatically according to the crossed arrangement of the systems, without the Disconnector requires special contacts for this.

The invention is illustrated schematically in the drawing. Figs. 1 and 2 show the known devices. The disconnector T is drawn in both of the open position. The high-frequency transfer systems S ₁ , K ₁ , S ₂ , K ₂ of Fig. 1 form two bridges to the power line, which is divided into two lines I, II and Γ, II 'by the disconnector. The coils S ₁ , S ₂ are coupled to one another for through high frequency traffic. At the same time, they serve to couple the high-frequency intercom F located at the separation point itself.

In Fig. 2, the systems S ₁ , K ₁ , S ₂ , K. are not coupled to one another. Rather, they are in series in the line and galvanically connect the line sections on the one hand at I, I ', on the other hand at II, II' with the disconnector T open. One coupled through S ₂

Call station F can only speak when the isolating switch is open, whereas it would be short-circuited with the switch closed. It would have to be coupled to the line by a special coil in order to enable it to speak in the latter case as well.

Fig. 3 shows the device according to the invention. The systems S ₁ , K ₁ , S ₂ , K ₂ are not coupled to one another and here either

ίο only connect the line sections galvanically with each other. Here, however, they bridge the line gap caused by the disconnector in such a way that they cross the line pieces at I, II 'and Γ, II with one another. The intercom F coupled by coil S ₁ can therefore speak at any time, regardless of whether the isolating switch is pulled or closed. To protect the intercom station against the risk of breakdown , an earthing choke E is provided in each crossover a, b. Branches III, IV of the line, which can disrupt the coordination of the systems S, K , are rendered harmless by throttles D.

In Fig. 4, each of the two connections a, b crossing the separation point leads via two differently tuned oscillation circuits 2V ₁ , JV ₂ . With this arrangement it is

possible without great difficulty by '> mutual detuning of the circuits the ' line for two high frequencies at the same time | to use. The figure shows how a call station F, which is located at this separation point, is _{to be coupled with both oscillation circuits JV 1} , N ₂ in order to also work for this call station! to use both frequencies, one for each direction of speech (outgoing and feedback). In the same way, you can also; more oscillation circuits are geschal- in series tet '. It is per se also possible to place several systems K, S of the j Fig. 3 parallel to one another between the blocking capacitors K ₁ , K ₂ for the same purpose, but here- |

with the matching of these systems not so | independent of one another and as simple as in the arrangement according to Fig. 4. The coils j of the oscillating circuits have taps so that the connection to the blocking capacitor K ₁ or K ₂ can be tapped on them. The capacitors of the oscillating circuits are accordingly also variable, as indicated.

Fig. 5 shows a simplified version.

of Fig. 4, in such a way that the one oscillation circuit K ₁ , which is permeable to the one high frequency, in the one crossover α. the other Λ ^Γ _{2 is arranged} in the other crossing b '. The call station F can again be coupled to both oscillation circuits, as the illustration shows.

Claims (7)

Patent-to sayings: 1. Device for high-frequency power lines occupied by high-frequency traffic, thereby characterized in that for the purpose of bridging the line gap caused by a pulled disconnector for high-frequency traffic, the separate branches of the line cross each other are each connected via a capacitor and a coil in series with it. 2. Device according to claim 1, characterized in that the transmission and reception system of a high-frequency intercom (F) is coupled to the connection (a or b) crossing the separation point. 3. Device according to claim 1, characterized in that in one of the two connections (a, b) crossing the separation point, two or more oscillation circuits (N ₁ , N ₂ ) each tuned to a different high frequency are arranged in series with one another and with them Oscillating circuits the transmission and reception system of a high-frequency intercom (F) is coupled. 4. Device according to claim 1, da- go characterized in that in each of the two connections crossing the separation point on a certain high frequency tuned oscillation circuit arranged and one of these on the one, the other on another high frequency tuned and further both are coupled to the transmission and reception system of a high-frequency speech station. 5. Device according to claim 4, data toc. by in that the \ ^r Getting Connected is taken from the tank circuit to the blocking capacitor of the intersecting connection to the coil of the oscillation circuit and the capacitor of this circuit is variable. 6. Device according to claim 1 to 5, characterized in that each of the two connections crossing the separation point via a choke coil Earth is laid. 7. Device according to claim 1 to 6, characterized in that in branches the power line ironless chokes for the purpose of sharp coordination of the Disconnecting bridges are switched on. 1 sheet of drawings.