DE826023C - Circuit arrangement for relay interrupter in telecommunication systems, especially telephone systems - Google Patents

Description

Circuit arrangement for relay interrupter in telecommunication systems, in particular telephone systems The invention relates to relay breakers, as used in telecommunications systems to generate periodic power surges for various Purposes are often used. Such arrangements consist of several, themselves Relays that switch each other on and off, whose response and _'11) decay determine the switching speed of the Unterhrechers. Is it in a telecommunications system necessary to bring about periodic switching processes in short and long time intervals, so one was previously forced to generate each type of these switching processes separately To provide interrupter devices, which is particularly then very uneconomical is when it is a connection device or line individually assigned Relay breaker acts.

The object of the invention is to provide the same relay breaker arrangement to be able to use them to generate power surges in short and long time intervals, what is achieved in that one of two mutually controlling relays has a counter-winding of high resistance with different tapping points a voltage divider is connected via changeover contacts., which is used by the determination the respective switching speed of the relay interrupter serving switching means being controlled.

Two exemplary embodiments of the invention are shown schematically in the drawing shown. Fig. I shows the basic structure of one out of a normal DC relay and a polarized relay consisting of two windings Relay interrupter, while in Fig. 2 the circuit of a time counting arrangement for telephone systems shown as one of the fields of application of the invention is.

In Fig. I, the normal DC relay of the interrupter is labeled I , TI and T II are the two windings of a polarized relay, of which the winding 1I is connected to an adjustable tap of the voltage divider P. The relay U switches the winding II from T at the taps of the voltage divider in order to change the switching speed of the interrupter arrangement. The commissioning of the circuit breaker, the contact is brought to is closed and thus the relay J t i over the contact to respond. It switches on the winding I of the relay T via its contact 2 i and the resistor W i and, with the help of the contact 3 i, reverses the voltage on the assignments of the capacitor Co. The polarized relay T responds and at its contact it opens the circuit for the relay 1, which drops out, whereupon the capacitor Co discharges through the winding I of the relay T and through the resistor W2. As a result, the relay T has a large drop-out delay which can be regulated by the high-resistance counter-winding II located at the right tap of the voltage divider P via the contact 4 u. A current surge was transmitted to the line core x via the contacts 5 i and 6 u. If the relay T drops out after a time determined by the setting of the tap on the voltage divider P, it closes its contact it and thus switches the relay J of the relay interrupter on again. These processes are repeated until the relay U responds via a contact n. It opens its contacts 4 u and 6 u and closes contacts 7 u and 8 u. As a result, on the one hand, winding II of relay T is connected to the left tap of voltage divider P and, on the other hand, the surge circuit controlled by contact 5 i is applied to line core y . Since the reverse winding II of the relay T is now at a much higher voltage, the release time of this relay is considerably shortened, so that current surges are transmitted to the line core y at shorter time intervals.

A possible application of the concept of the invention for an arrangement for time counting in telephone systems, which is shown in FIG. 2, will now be briefly described. When the arrangement is occupied, the contact 9c is closed and thus a circuit for the winding I of the relay J i is established via the contacts io a, II t I, 12Z and 13Y. It switches on via its contact 14 i I and the resistor Wi i, the winding I of the polarized relay T i, which opens its contact i I t I and closes the contact I2 t I, so that the relay J i is switched off and the clock relay Z via the contact 13 y and its winding I and via the resistor Wi 3 is excited. It interrupts its contact 12 z and closes a discharge circuit for the capacitor Co via the contact i4z and resistor Wi 2 , which was charged via the contact 15 ii. As a result, the armature drop of the relay T i is delayed. A high-resistance counter-winding II of the polarized relay T i is connected to the right tap of the voltage divider Po via the contact 16 ui. As soon as the armature of the relay T i is returned to the rest position and the contact 12 t I is opened, the relay Y short-circuited via the contacts 12 t I and 13 y speaks via its winding I and the contact 17 z in series with the winding I of the relay Z on, whereupon the relay J i is switched on again via the contacts 18 z and i9 y .

The relay J i had switched on the winding I of the drive magnet WR of a stepping mechanism with the switching arms ier I and wr II when it responded via the contacts 20 c and 2 1 ii. This switching mechanism serves as a time memory for the counting arrangement. The switching arms a, r I and wr II take a step. When the relay J i is switched on again, as has already been described, the alternating switching on and off of the relays J i and T i of the relay interrupter begins anew. The discharge circuit for the capacitor Co now runs via the contact 22 y, while the switching mechanism WR performs a further step. When relay T i responds, winding 1I of relay Y is switched on via contact 12 t I and contact 22 y, thus bridging the holding circuit for winding I of relays Y and Z. As a result of the low resistance of winding 1I of relay Y, relay Z cannot hold itself parallel to it and drops out. If the polarized relay T i puts its armature back into the rest position after the end of the second operation of the interrupter device, the circuit for the holding winding II of the relay Y at contact 12 t i is interrupted, so that both the circuit of the relay interrupter and that of the clock relay Z and Y are returned to the idle state shown. The processes now start again and continue until either relay A is energized or the memory switching mechanism reaches its thirtieth contact. The relay A is controlled by the calling subscriber station and indicates the end of the call, while when the thirtieth switching position of the switching mechanism WR is reached, the connection is forcibly disconnected and the multiple counting initiated. If the relay A responds, the following circuit is established regardless of the position of the switching mechanism WR: positive pole of the battery, switching arm wr I, contacts 24 w, 25 a, 26 wr, winding 1I of relay J i, negative pole of the battery. The relay I i responds and switches on the winding I of the drive magnet WR via its contact 21 ii, which by opening its contact 26 wr interrupts the circuit just described for the winding II of the relay II, which then drops out and at contact 2 1 i I switches off the drive magnet WR. Thereupon the contact 26 -, c? R is closed and thus the relay J i is energized again. The interplay between these two magnets continues until the switching arm -, c, r II reaches contact 30 and thus turns on winding II of drive magnet WR and winding I of relay W via contact 27 ui. The latter closes a holding circuit for its winding II via its contact 28 W and the switching arm to I. At the same time, by closing the contact 29 w, the relay U i is excited, which via its contact 30 ui the winding II of the relay T r to the left The voltage divider Po is tapped, with the result that the fall time of the polarized relay T i is considerably reduced. At the same time, the winding I of the relay J i is switched on via the contacts 9 c, 4o a, 31 ui, 11 t i, 12 z and 13 y, which now initiates the switching processes described above with the relay T i again. Each time the relay J i responds, a counting current surge is applied to the counting wire Za via the contacts 32 ii and 33 ui and, at the same time, the drive magnet WR is actuated via the contact 21 ii. These processes continue until the switching arms wr I and wr II reach the zero position shown in the drawing, in which the holding circuit for the winding II of the relay W is interrupted by the switching arm wr I. By opening the contact 29 w, the relay U i drops out and interrupts the circuit for the relay J i at contact 31 ui. In this way, the relay interrupt is shut down and five counting current pulses, for example, have been transmitted to the counter of the calling subscriber station via the counting wire Za. At the same time, in a manner known per se, not shown, the upstream voters are triggered, whereupon relay A also drops out again.

As can be seen from the above description, there is a breaker circuit according to the invention a simple means to the same relay breaker for the To use the emission of power surges at short and long time intervals.

Claims (5)

PATENT CLAIMS: i. Circuit arrangement for relay interrupter in telecommunication systems, in particular telephone systems, characterized in that one (T) of two mutually controlling relays (I / T) has a counter-winding (T II) of high resistance which is connected to different tapping points of a voltage divider (P) via changeover contacts (4 u, 7 u), which are controlled by switching means (U) serving to determine the respective switching speed of the relay interrupter. 2. Circuit arrangement according to claim i, characterized characterized in that the opposite winding (II) to the voltage divider (P) lying relay (T) is designed as a polarized relay, its response winding (T I) when their excitation current is interrupted by the discharge current of a capacitor (Co) is influenced. 3. Circuit arrangement according to claim i, characterized in that a relay (U) is used to control the switching contacts (4 u, 7 u) , which carries the current impulses given by the one relay (1) of the interrupter via a further switching contact (6u, 8u ) of the relay (U) transmits to different circuits (x, y) depending on its state of excitation. 4. Circuit arrangement according to claim i for arrangements for multiple counting in telephone systems, characterized in that that the reverse winding (T i II, Fig. 2) high resistance to determine the talk time at a low voltage of the voltage divider (Po) and for sending out the counting current surges after a switching means (U i) becomes effective, it is at a high voltage. 5. Circuit arrangement according to Claim 4, characterized in that the surge relay (J i) of the interrupter to determine the talk time at long intervals given current surges on a storage device (WR) and the short counter current surges Via the changeover relay (U i) controlled contacts (33 u i) on the counting circuit (Vein Za) are transmitted.