DE857215C - Circuit arrangement for telephone systems with branch points located on a common line - Google Patents

Description

Circuit arrangement for telephone systems with a common Line branching points In telephone systems with on a common line lying junctions, as they are, for. B. used for train monitoring systems, it is sometimes desirable that the calling station, for example the central office, receives a return signal from which it recognizes that the call circuit to the selected Junction is switched on. This back control is usually carried out in the Way that a reverse control circuit is closed with the call circuit at the same time that goes through the handset of the calling station and this the speaking of the alarm clock or the like. However, such an arrangement is not possible use in any case. In particular, difficulties arise with such systems for back control, in which the activation of the call circuit by a The frequency sent by the calling station takes place and with the shutdown the frequency and the call circuit is interrupted again. So it is a frequency at the common during energization of the call circuit Management. Would now in such a case at the same time a back control circuit are closed to the calling point, so complicated sieve chains would have to be provided that only let the alarm clock frequency through to the listener of the calling station, on the other hand, the one switched on by the calling station to control the call circuit Lock frequency. The effort to carry out a back check only for the purpose of would therefore be relatively large and the profitability of such systems adversely affect.

The invention shows an arrangement that makes it possible in such Cases to get along without complicated sieve chains and still a flawless return check perform. You achieve this by the fact that through the selection devices Branch point controlled when the call circuit of this branch point is switched on participating switching means after the triggering of the selection devices the call circuit delayed switch off and thereby temporarily a back control circuit to the calling Close position.

The invention is illustrated below with reference to the in the drawing Embodiment explained.

Fig. I shows the central point from which the common line La, Lb leads to the branch points, one of which is shown in Fig. 2. The central station consists essentially of the selection device with the keys T i to T 6 and - the relays i to 6 assigned to the individual keys. Frequency generators S i to S6 are provided for the transmission of the various frequencies. The frequency generators consist of self-interrupters that chop up a direct current in different rhythms. The chopped up direct current is transmitted as alternating current to the common line by means of a transformer. When the system is idle, they are on the common line in the central office. the voice-controlled receiving equipment required for the call from a branch point. Either a loudspeaker or a telephone relay A, which controls a call circuit, is used as the receiving device. For telephone communication with the branch points, a headset is also provided for the officer in the central office. The branching point shown in Fig. 2 has two resonance relays R, R i connected to an autotransformer and the auxiliary relays D, E, F, H , which control the call circuit and the callback call.

The mode of operation is as follows: It is assumed that branch point 26 is to be called from the central office. For this purpose, the button T2 is first pressed, whereby the relay 2 assigned to the button is activated in the following circuit: +, n "I, ml, R, T 2, 2 (winding I), -.

In this circuit the relay R also responds, which with its contact s "switches on the relay B and all frequency generators S i to S6. The contact b ° of the responding relay B creates a holding circuit for the relay 2 independent of the button T 2 The circuit runs through +, bv, n ", m", y ', 2 ", 2 (winding II), -. After releasing the button T 2 and the associated drop in relay R, the excitation circuit for relay B and for the frequency generators S i to S 6 is maintained via contacts n 'and b1It. After the relay R has dropped out, the relay M in the holding circuit of relay 2 will respond, which was previously short-circuited. The relay M opens its contacts m1 'and in'. The latter contact removes the short circuit for relay N, which, however, only comes into operation when the second frequency is transmitted. The frequency generators work in a self-interrupting circuit. However, only the frequency generator that is connected to the primary winding of the transformer Tr2 through the selection relay 2 by means of the contact 21 is effective. The direct current running via the contacts n ', b'n, s 2', 21 and via the primary winding of the transformer Tr2 is chopped up by the contact s2 'in the rhythm of the frequency assigned to this frequency generator. The chopped up direct current is inductively transmitted to the secondary winding of the transformer Tr2, which is connected to the common line La, Lb leading to the branch points through the contacts bl.v and b ° 'from the voice-controlled receiving devices of the central office.

The frequency current connected to the common line in this way runs through resonance relays R of all the branching points that are switched on when the branching points are inactive. However, only the resonance relays of the branch points respond, which are matched to the transmitted frequency. When the resonance relay R responds, a relay D is switched on via contact r, which in turn switches on the drop-out delay relay E with its contact d11. Contact e 'prepares the connection of the resonance relay RI, while the contact eIll <las 1Zesolializrelais R switches off, which, however, remains switched on for the time being through contact d111. Contact ev prepares another auxiliary relay F. In the central office, the officer sees at the lamp field on which lamp L2 lights up that the selection relay 2 has responded and thus the transmission of the first frequency has been effected. The officer now presses the T6 button in accordance with the second digit of the station number, which causes the relay 6 to respond via its winding I. In the excitation circuit of the relay 6, the relays R and N respond, the short circuit of which, as already mentioned above, was canceled by the relay M. The contact n. "Opens the holding circuit for the relay 2, which now falls. As a result, the frequency generator assigned to the relay 2 is also switched off at the contact 2I. Instead, the frequency generator S6 assigned to the relay 6 comes into effect, the one with the contact 61 is connected to the primary winding of the transformer Tr2 and now the direct current flowing through the primary winding is chopped in the rhythm of the frequency assigned to the frequency generator S6. As long as the relay R is energized, the contact r11 keeps the relay B and the frequency generators switched on. Due to the second frequency transmitted via the common line, the resonance relay R i, which is tuned to this frequency, responds via the contacts e1 and d111 in the branch point 26. The contact d111 was in its rest position after the end of the first frequency transmission due to the interruption of the circuit of the relay D On the other hand, the contacts of the relay remain s E still transferred, as the latter is delayed. When the resonance relay R i responds, the relay F is switched on via the contact ri and the still folded contact ev, which closes the call circuit via the alarm clock via the contact f1. The excitation of relay E is maintained by the contact f °. Via contact f1, a circuit for relay H is closed at the same time, which is connected to a holding circuit via its contact hlv and via contact ev. In the lamp field of the central office, instead of lamp L 2, lamp L6 is now switched on, which indicates to the officer that the second frequency has been transmitted. After releasing the button T 6 , the relays 6, R, N drop out. The switching on of the frequency generators and the relay B is canceled by the contact r11, so that the relay B immediately drops out and with its contact bv prevents a holding circuit from being established for the holding winding 1I of the relay 6. The selection device of the central office is thus returned to its rest position. After the second frequency has been switched off from the common line, the resonance relay R i drops out, so that the circuit for the relay F is also interrupted. Before, however, the opening of the contact for the relay E leads to a dropout, which in turn interrupts the holding circuit of the relay H with its contact el, the relay H, which has already dropped out, is temporarily activated via the contact f111 of the relay F that has already dropped out and via the contact h11 of the relay H, which is still kept energized Circuit through the winding II of the induction coil 1 closed, so that the call running through the contacts ey and h1'v as well as the alarm clock and the winding I of the induction coil I is transmitted back inductively as a call return control to the central office. After the relay E has dropped out, the relay H is also de-energized again, so that now all the relays of the branch point have returned to their rest position. When the call is accepted, the branch point switches to the common line by means of the hook switch Hu.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for telephone systems with branch points located on a common line, in which the calling point of the selected branch point is reported back to the calling point by a control circuit, characterized in that the branch point controlled by the selection devices (R, R i), when the call circuit is switched on ( Alarm clock circuit) this branching point involved switching means (F, H, E) after the triggering of the selection devices switch off the call circuit with a delay and temporarily close a back control circuit via contacts (f111, hI1) to the calling station. 2. Circuit arrangement according to claim i, characterized in that the call circuit (alarm clock circuit) runs over a winding (I) of the induction coil (7) of the call station, by means of the response of the calling organ (alarm clock) inductively to the back control circuit is transmitted. 3. Circuit arrangement according to claim i and 2, characterized in that the closure of the back control circuit is limited by the successive fall of relays (H, F) involved in controlling the call circuit. d. Circuit arrangement according to Claim i for systems in which resonance relays tuned to different frequencies are provided as selection devices in the branch points, characterized in that the switching means (F, H, E) which control the call circuit (alarm clock circuit) and the back control circuit are controlled by the or the resonance relays (R, R i) of the branching point are dependent.