DE665857C - Circuit arrangement for signaling by means of alternating currents in telephone systems - Google Patents

Description

Circuit arrangement for signaling by means of alternating currents in telephone systems The invention relates to an arrangement for the transmission of signals in telephone systems.

Si signal transmission devices of the type according to the invention are z. B. used in the production of remote connections in such systems where alternating currents in the voice frequency range are used for signaling. In known. Systems of this type are z. B. alternating currents sent over the lines, which consist of a base or carrier frequency of rooo Hz, in a certain rhythm of. z. B. 15, 25 or 35 periods modulated or interrupted exist. At the end of the lines, ie at the point where the signals are received, receiving devices are provided that are tuned to one of these lower modulation or interruption frequencies. The carrier or fundamental frequencies as well as the interruption frequencies can be chosen quite differently. Systems of a different type also use several transmission channels, ie different carrier frequencies.

In the known signal transmission systems of this type one uses also for receiving the different signals signal receiving devices and in these resonance circuits, which are matched to those used for signaling Carrier or., NIodulatiotl, sfrequen.zen for the execution of the different switching processes. However, these devices are cumbersome and expensive apparatus before. Others of these signal transmission systems that operate with frequencies in the speech range work, use sensitive polarized relays that are in the output of receiving rectifiers lie. The resonance circuits with the self-induction coils and capacitors, which are used in all of these systems are, as I said, complicated and expensive Facilities.

A main requirement for those receiving the signals or the power surges Facilities, the signal receivers, is selectivity, i. H. the recipients must be set up in such a way that they can be passed through the same lines by others in such systems flowing streams, preferably the speech streams, are not influenced. These However, this requirement is known to be difficult to meet, mainly because for the current surges for obvious reasons alternating currents of an im area the speech or sound frequencies lying frequency can be selected. These difficulties occur with both electrically and mechanically tuned.ti receiving devices on.

The object of the invention is now to provide a selective signal transmission device z ü 'create who are very keen on speech frequencies or the low-frequency interruption frequencies is tunable and which can be produced cheaply and easily on a relatively small scale Space is to be accommodated. This object is achieved according to the invention in that the signal receiver has one or more mechanically tuned resonance devices (2o to 22 and 68 to 70 with independent primary or secondary coils with separate iron cores, the individual windings (23 to 28 and 3o to 35) are arranged in such a way that any mutual coupling is prevented is and a Strom.fluss in the secondary windings only through the one between the latter oscillating armature caused changes in the magnetic Field is caused.

The signal receiver according to the invention consists of one or more Devices, each of which is a mechanically tuned resonance device each with a downstream rectifier, e.g. B. a discharge tube with in their Anode circuit arranged receiving relay contains. The resonance devices .contained a take-up or secondary coil and a drive or. Primary coil, both in two windings each divided and connected in series. The drive coils of the existing Resonance devices, connected in series, are located in the bridge diagonal a Graetz full-wave rectifier (e.g. consisting of dry rectifiers). This rectifier, if necessary via a preamplifier, which is on the Line supplied to incoming signal current surges. The coils are independent of each other, d. H. arranged without mutual coupling. Between the coils, @d. H. by doing The air gap between the cores of the coils is one that oscillates around a vertical axis Armature attached, which is driven by the drive coil in the rhythm of the low-frequency alternating current, which corresponds to the natural frequency of the armature is set in vibration, such that one end is between the cores of the drive coil and the other End moves between the cores of the take-up reels. As a result, the Field change in the pick-up coils Current surges of the same frequency, d. H. the Natural frequency of the: 4nker or the frequency of the incoming signal alternating current, generated. The current surges generated in the pick-up coils become the grid one The discharge tube is supplied, in the anode circuit of which the signal receiving relay is located. The current flow in the anode circuit for actuating the Re-`lei corresponds in each case to the Duration of the signal current surges arriving via the line.

The invention is based on the in the drawing (Fig. I and 2) .shown exemplary embodiments.

Fig. I shows the arrangement according to the invention low-frequency modulated or interrupted carrier tone frequency and Fig. 2 at Use of a urimodulated audio frequency as the signal frequency.

Fig. I shows an embodiment in which the transmitted signal streams arrive via the transmission line L at the receiving device. In the exemplary embodiment, a carrier frequency of 100 Hz is assumed. Uni now to receive different different signals, this carrier frequency is in different rhythm, z. B. 15, 25 or 35 periods interrupted. In bridge to the. The wires of the line L are the receiving device, the input circuit 4 .; 5 is matched to the signal frequency arriving via the line L and intended for this receiver. The absorbed current surges -grounds passed through the input transformer 2 to the grid 8 of an amplifier tube 6. Itn the anode circuit of the same is the primary winding of the output transformer 1q .. The secondary winding of this transformer is connected to a full-wave rectifier 15, the z. B. is formed from dry rectifiers in Graetz circuit connected. In the bridge diagonal of the full wave rectifier are the mechanically tuned resonance devices 20, 21, 22, namely their coils 23, 2q., 25, 26 and 27, 28, called drive coils. The resonance devices 20, 21, 22 are each tuned to a different interruption frequency from 15 or 25 or 35 Hz. Depending on which of the frequencies mentioned is contained in the signal oscillation arriving at the signal receiver, the signal circuit A, B or C is excited. At z. B. 15 Hz, the signal circuit A, at 25 Hz, the signal circuit B and at 35 Hz, the signal circuit C to.

Each resonance device, e.g. B. 2o, comprises two drive coils 23 and 24 and two take-up reels 30, 31 and one in the air gap between the cores of these coils vibrating armature 36, the frequency assigned to this device of 15 Hz is tuned. Just one through the drive coils recorded Signal of the specific natural frequency of the armature of 15 Hz actuates the armature 36 and causes it to vibrate in this rhythm. The drive as well as the take-up reels are independent of each other, i. left decoupled from one another, so that only the through the armature movement between the cores of the pick-up coils results in the field change generated in these coils a voltage which has the same frequency as the signal frequency arriving via the line and exciting the drive coils 23, 24. This voltage is transmitted to the grid of the discharge tube and that in it The increased current operates the l; iiipfangsi relay q (-) in the anode circuit. That Relay 4.6 is arranged so that it responds when excited by the @Xnoclenstroni and a circuit, e.g. B. for the Signallainpe.I7, the atis of the Ortsliatterie.l.9 is fed, closes. In the anode circle of the discharge tube 4o lies furthermore, in parallel to the receiving relay .I6, another capacitor q.5 in series finite a resistor 44. The order of magnitude of this capacitor and `. 'resistor is dimensioned so that the discharge process in the anode circuit is interrupted immediately, when the incoming signal current surge has decayed in the input circuit.

The signal circuits B and C work in the same way as previously described for circle A, the only difference being that they are each on another frequency, e.g. B to 25 and C to 35 Hz, respond, corresponding to the Natural frequency of the armature 37 to 38. -The arrangement is of course not restricted to the three signal circuits shown in an exemplary embodiment, of course it can also more or less such circles could be provided. In certain cases Of course, you can also omit the signal lamp 47 with the relay .I6 and the discharge current Let the Röhreq.o act on another display device.

The arrangement according to A.bb. Figure 2 shows an arrangement for a multiple signal system with unmodulated signal frequencies in the voice frequency range. For signal transmission In this exemplary embodiment, audio-frequency currents are used via the line L '. A single tone frequency or a combination can be used as the signal frequency such frequencies. A combination of tone frequencies is preferably used in the range from 500 to goo Hz. B. set up so that you have four Frequencies of e.g. B. 500, 6oo, 75o and goo Hz applies and the resonance devices 68, 69, 70,; 1, which correspond to the resonance devices explained above in Fig. I, each tunes to one of these frequencies. You can z. B. the following frequency combinations send out: 500, 750: and 900 or 5oo, 6oo and 700 or 500, 6oo and goo. The embodiment according to fig. 2 is chosen for the work finitely such frequency combinations.

In other respects, this arrangement works in the same way as in Abl. i shown arrangement. The individual audio frequency current surges reach aen input circuit, input transformer 62, which is connected to the grid circuit of the amplifier tube 03. The primary winding of the transformer 67 is located in the anode circuit of the same. The terminals of the secondary winding of the transformer f, are the resonance devices 68, 69, 70, 71 In. Row connected and connected. It is assumed that the resonance device 68 is tuned to a frequency of 5000, 69 to a frequency of 600, 70 to a frequency of 750 and 71 to a frequency of goo Hz. Upon arrival z. B. the first-mentioned frequency combination 500, 750, 900 Hz, the resonance devices 68, 70 and 71, as described above in the arrangement according to Fig. the signal circuits D, F and G are energized. This causes the receiving relays 8o, "2 and 83 to respond and actuate their contacts. When the first relay M responds, a circuit for the relay 84 is established, which is connected to earth at the closed contact of the relay 8o, via the contact of the relay 8i, the winding of the relay 8.1. runs to the battery, earth. The response of the relay 84 switches off the signal lamps F 'and G' of the signaling device and closes a circuit for the signal lamp E ' Relay 81, make contact go of relay 8.4 and make contact of relay 82, make contact gi of relay 84, make contact of relay 83, make contact 92 of relay 84 and the signal lamp E 'after the battery 7oo Hz, causes the response of the resonance devices 68, 69 and 70 and thus the tubes 72, 85 and 86 of the signal circuits D, E and F and four relays 8o, 81 and 82. The response d These three relays close a circuit for the signal lamp F ', which runs from earth to the contact of the relay 8o via the normally open contact of the relay 81 and the relay 82 to the normally closed contact gi of the relay 8q., the signal lamp F' to the battery, earth. The third combination does not include the frequencies 500, 600 and goo and causes the response of the resonance devices 68, 69 and 71 and at the same time the tubes of the signal circuits D, r and G and their relays 8o, 81 and 83. This creates a circuit for the lighting of the Signal lamp G 'closed, which runs from earth at the contact of relay 8o, make contact of relay 81, break contact of relay 82 and make contact of relay 83, break contact 92 of relay 8: 1, signal lamp G' to battery, earth.

Claims (1)

PATENT CLAIMS: i. Circuit arrangement for signaling with alternating currents in telephone systems, characterized in that the signal receiver contains one or more mechanically tuned resonance devices (2o to 22 and 68 to 71) with independent primary and secondary coils with separate iron cores, the individual windings (23 to 28 and 3o to 35) are arranged in such a way that any mutual coupling is prevented and a current flow in the secondary windings is only caused by the changes in the magnetic field caused by the armature oscillating back and forth between the latter. Circuit arrangement according to Claim i, characterized in that the secondary windings are connected to a signal circuit in which a hot cathode tube with the signal receiving relay is arranged in its anode circuit and, in parallel, a resistor in series with a capacitor for the purpose of immediate interruption of the anode current when the current surge dies down. 3. Circuit arrangement according to claim i, characterized in that one end of the armature (36) tuned to a specific natural frequency lies in the air gap between the primary coils (23, 2q.) Through which the incoming signal currents of the armature frequency flow and is driven by them, that is, it is set in oscillation, while the end, which oscillates with the same rhythm, is located in the air gap between the secondary coils and causes the changes in the magnetic field through its movement. Circuit arrangement according to Claim i, characterized in that the primary coils (-23 to 28), connected in series, lie in the bridge diagonal of a full-wave rectifier circuit (15) which is possibly connected to the input circuit of the signal receiver via a preamplifier. 5. Circuit arrangement according to claim i, characterized in that the signal circuits (DG) are influenced in certain different compositions or order as a function of the different signal frequency combinations arriving via the line. 6. Circuit arrangement according to claim 5, characterized in that the contacts of the signal relays (8o to 83) of the individual signal circuits (D-G ') are arranged in such a way that depending on the respective. Composition or sequence of response of the signal circuits certain different signals are triggered.