DE704359C - Circuit arrangement for telephone systems with dialer operation - Google Patents

Description

Circuit arrangement for telephone systems with dialer operation The present The invention relates to a circuit arrangement for telephone systems with dialer operation, in which there is a tap after the occupancy by an upstream voter automatically adjusts to one of these accesses via one of several accesses.

The invention aims to create an arrangement that makes it possible to that the taps are automatically activated via a certain access after their occupancy can adjust to this access without special in the individual accesses Identification relays must be arranged. Furthermore, over the used Maintain access to the occupancy and blocking circuit and, at the same time, to the other accesses are blocked against other occupancy.

By avoiding special identification relays in the entrances occurs not only a saving in switching means, but the arrangement is through -The omission of a large number of contacts is very simple and reliable.

The setting of the tap, which is based on the should set the access used, can be carried out in an operationally reliable manner, with double assignments of the same tap via different accesses with security be avoided.

Arrangements are known in which previously set mixer selectors check for pulse transmitters via a special auxiliary arm without initially blocking the pulse transmitter against other occupancy. A pulse transmitter provided in this way is only blocked after a group selector occupying a mixer selector has been checked via a second auxiliary arm of the mixer selector. During this process, relays that are in the occupancy and blocking circuit coming from the group selector respond, ie Forwarding of others not in use set to the same impulse transmitter: 1lischwähler and the implementation Identification of a certain access of the impulse transmitter via a third switching poor of the mixed voter.

Compared to these known arrangements can in the present invention the assignment, blocking and marking on the pick-up is carried out via a single wire will.

Other arrangements are known in which the blocking of a pulse transmitter with the help of chain contacts of identification relays located in special auxiliary accesses is carried out. In these arrangements, the switching mechanisms are accordingly assigned not over the entrances themselves, so that the upstream voters over which the impulse transmitter is switched on, must have a larger number of switching arms.

The invention consists in that both the occupancy process as also the test process of the tap to determine the access currently being used runs over the same wire and switching means are located in this wire, the one Blocking of all other parallel entrances by the upstream voter allow, and that the test relay of the tap to determine the access used in such a way connected one after the other with the switching means located in the accesses is brought that it is only when the tap is set to the access used comes into effect.

The arrangement according to the invention is particularly advantageous for systems with those according to the occupancy of the tap to determine the used Access certain switching measures are to be carried out, such as this is the case, for example, with pulse transmitters or zone detectors. at these switchgear are corresponding to the identification of one of the entrances Series of current impulses sent or corresponding markings on switchgear transferred to determine the amount of the fees. The criterion for sending the series of current impulses or for the implementation of the determinations is used when finding of the marked access given by addressing a test relay of the tap.

Particularly advantageous embodiments of the invention consist in that the test relay of the tap used to determine a marked access is connected in parallel to rectifiers or resistors that are in the marking lines. is held, and that these switching means contain are really nicdcrohmig trained, so m the blocking conditions in the entrances ` t " lkipigrUN-ch when producing a response current circuit for the mentioned test relay only un- can be changed significantly.

Exemplary embodiments of the invention are shown in the drawings.

FIG. Z shows a current impulse transmitter Sp with the switching arms spa, spb, spc spd and the switching magnet Dsp. The current impulse transmitter is occupied by the selector lY, which is designed as a line, meter or group selector and has the switching arms aw, bw and czu. The drive devices used to advance the switching arms of the selector W have been omitted since they are not important for the invention. The impulse transmitter Sp is put into use via one of the accesses Coo, Co .. to C.19. Depending on the occupancy via one of these entrances, three or four series of current impulses are transmitted, the value of the last series of current impulses to be sent by the selector Sp also being determined by the occupied access. The selector W2 shown at the outgoing end of the connecting line hLB seeks out a free outgoing line when the impulse transmitter is occupied. The selector W2 has the switching arms aw2, bw2 and cw2, its indexing magnet is designated by Dw.

For now, the switching processes to be described which occur when the StromstößsenderSp has been taken by assignment of access Co, in use.

If the selector W is set to the line Coo, the following occupancy circuit occurs when the impulse transmitter Sp is free: earth, tripping or not shown. Switching means on test relay PA, windings II and I of test relay PA, switch arm c7u of selector W, access CO, resistor Wil, winding I of relay C, switch arm spb of impulse transmitter Sp, resistor Wi ", battery, earth. In this circuit they speak Relays PA and C on., Relay PA blocks the access found by closing contact 3 pa and, due to the multiple switching of the low-resistance resistors in the other entrances, also the other entrances against occupancy by another selector W. Relay C is delayed on, since its winding II is short-circuited via the contact qc. When the relay responds, the contact qc is switched over, whereby the battery is applied directly to the winding I of the relay G via the resistor Wi13., The contact 5c causes the relay B to be excited its windings I and II. This circuit runs from earth via KorL-ztakte 5c, rotz or 24p, 17i, winding and II of the relay B to the battery, earth kt 6 c prepares a test circuit running over the windings II and I of the relay P for the selector W2. The contacts 7c and 8c cause the energization of the relay A via the winding III in the following circuits: earth, contacts 7c, 26p, winding III of the relay A, contact 8c, battery, earth. The contact 9 c prepares a premagnetization of the relay H via its winding II.

If the relay A responds, it actuates the contacts io a, II .a and 12 a. The response of the relay B causes the actuation of the contacts i3-b, 1 ¢ b and 15 b. When contact 14b closes, relay J receives a current stole via its windings I and II in the following circuit: earth, contacts 5c, 24p, windings I and II of relay T, contacts 14b, 33h, resistance Wi ", battery, earth The relay J responds and actuates the contacts 16i to 21i. The contact 16i causes the rotary magnet Dw ;; of the selector W to be excited in the following circuit: earth, contacts 5c, 24p, loa, 16i, rotary magnet Dw2, battery, earth The rotary magnet Dw switches the switching arms aw2, bw2, cw. Of the selector W one step further if the line on which the switching arms of the selector W2 are occupied. The contact 2 dw2 of the rotary magnet DW2 is opened so that the Relay B is de-energized. If relay B opens contact 14. b, relay J drops out. Relay B is again energized via contact 17i which has dropped out, while rotary magnet DW2 is de-energized by opening contact 16i B now causes the excitation d again it relay J via contact 14 b, whereupon the play just described between the relays B, J and the rotary magnet DW2 begins again. The selector W # is accordingly switched on until the test relay P responds when a free line is found and the contact 24p flips over. For example, if the line shown in the drawing is the first line found free by the selector W2, the following circuit is established via test wire c2 @: Earth, contact 6 c, windings II and I of relay P; Switching arm cw2, line Lc2, occupancy switching means (not shown), battery, earth. The relay P switches on the outgoing speech wires with the contacts 22 p and 23 p. Contact 24p causes relay T to drop before contact 14b has opened. Contact 25 >> blocks by short-circuiting the., <;, WV; cklung II of the relay P the found line. The contact 26p opens the excitation circuit for the winding III of the relay A. 1), the relay A drops out, because meanwhile the "> 5econtact i gi has assumed its rest position. The contact 27P short-circuits the winding I of the relay B, so that the selector 97 works with delayed control relays (T and B) after relay P responds.Contact 28p applies the character Frz to winding II of relay A so that it is inductively transmitted via winding I to the calling station will.

After relay P responds and relay A drops out, relay B is excited in the following circuit: earth, contacts 5c, ioa 17i, windings I and II of relay B, battery, earth. Relay J is energized again via contact 14b, so that the rotary magnet Dsp of the impulse transmitter is excited in the following circuit: earth, contacts igi, 12a, 15b, rotary magnet Dsp, battery, earth. The switching arms of the impulse transmitter are switched one step further, the contact i dsp is opened. The relay B drops out because the holding circuit, which runs via the contact 13 b and the contact i dsp, is interrupted. The contact i4 b = opens the excitation circuit for the relay J. The falling contact 17i again excites the relay B, which also causes the relay J to respond again. The rotary magnet Dsp receives a current impulse again via contact 19 i , so that the switching arms of the selector Sp assume position 2. If now, in the manner already described, first relay B and then relay J de-energize, relay V is energized via position 2 of switch arm spc in the following circuit: earth, battery, contact gc, relay V, contact 21i, switch arm spc in position 2, contact 34h, earth. The relay V responds and establishes a holding circuit for itself via contact 31 v, which runs to the contact toi. The relay H receives fault current through its winding II. The contact 30v opens the short circuit across the winding I of the relay B, so that it no longer works with a delay. As a result, the current impulse ratio determined by the cooperation of the relays J and B is brought into the form suitable for the further establishment of the connection. The contact 29v prepares a surge circuit for the emission of the outgoing current surges. The control voltage required for the emission of current surges is applied to line Lb2 via contact 32 v. Speaks when the contact 17i by carrying out the second step of the selector Sp relay B again, so via contact 1 1, the excitation b of the relay J. About contact ig i the emission takes place of a current pulse via the line lag. The emission of Current surges are terminated by de-energizing the relay h. By closing the igi «= contact, the switching arms of the selector Sp are switched to position 3 by energizing the rotary magnet Dsp. in this the relay B drops out by opening the contact i dsp, whereupon the relay J is also de-energized. The time of de-energization of relay J corresponds to the termination of the first transmitted current impulse (opening of contact i8i). The relay TI drops out as soon as the contact toi is opened and earth is not applied to the switching arm spc. The relay V drops out in position 3 of the selector Sp. A power surge has been emitted. When contact 17i drops out, relays B and J are again energized, so that selector Sp is switched to position 4. Further transmission of current surges via the contact 18 i is prevented because the contact 29 v has already assumed its rest position in position 3 of the selector Sp. The control voltage was switched off from wire Lb2 at contact 32 v.

The impulse transmitter Sp is switched from position .4 to position 6 by the mutual play of relays B and J in the manner already described. If the selector Sp reaches position 6, the relays J and L 'are energized. By opening the contact i dsp controlled by the rotary magnet Dsp, the relay B is brought to fall and the relay J is de-energized by opening the contact 14b. When contact 2 1 i is closed, the following circuit is established for relay V in position 6 of selector Sp: earth, battery contact gc, relay V, contact 2i i, switching arm spc, contacts 6, 341i., Earth. The relay V prepares by moving the contact 29 v for the transmission of a second series of current impulses that are permanently set on the impulse transmitter. This series of impulses consists of ten impulses.

When relay J drops out, relay B is re-energized via contact 17 i. The circuit for energizing relay J, described earlier, is established via contact 14b. The relay J brings i the first current impulse of the second impulse series to be emitted by the impulse transmitter to effect by closing the contact 18 i. The rotary magnet Dsp is excited by moving the contact igi, whereupon the selector Sp moves to position 7 . The fall of the contact i8 i in position 7 of the selector Sp ends the first rush of the second series of rushes. The relay V determines the length of the series of impulses to be transmitted and remains in position 6 when relay J is addressed via contacts 20 i, 31 v and 9 c and when relay J is de-energized via contacts gc, 2i i, switching arm spc of selector Sp. to 15, in which earth is applied to the corresponding contacts in the contact bank of the switching arm spc via contact 34 h.

If the selector Sp reaches the position 16, after the relay J drops out (opening of the contact 2o i), the relay V also drops out, since ground potential is no longer applied to the contact 16 in the contact bank of the switching arm spc. Accordingly, ten power pulses are transmitted when the positions 6 to 15 are exceeded by the selector Sp. When relay h drops out, the outgoing surge circuit, which runs over wire La, is interrupted at contact 29v. The winding I of the relay B is short-circuited by contact 30v, so that the selector Sp is now switched on with slow steps (both the winding I of the relay B and the winding I of the relay J are short-circuited).

If the switching arms of the selector Sp reach the position i9, the following circuit for the relay H is established, assuming that the impulse transmitter Sp has been occupied via the access Coo: earth, switching means (not shown) on contact 3 pa, winding I of the relay PA, switching arm cw of selector W, access Co, of selector Sp, contact 1 g in contact bank spa of selector Sp, winding I of relay H, winding I of relay H when the switching arm spa hits ground. The resistor Wil lying parallel to the winding I of the relay H enables the relay H to respond via the winding I. This response is supported by the fact that the winding II of the relay H when the switching arm spa hits the contact 19 via the contact toi was pre-excited. The resistance values of the resistors Wil to Wio and the resistance value of the winding I of the relay H are kept the same or approximately the same and can range from 4o to 6o Ohm, so that the resistance value of the test relay PA of the occupying selector W for the winding 1I with about 100 ohms and for winding I with about 60 ohms can be assumed. The selector W can therefore be trained with the usual test relays, and it is still possible to block the other accesses properly when one of the accesses is blocked, since for the test relay of a voter adjusting to a blocked access, its test relay according to the above assumptions checks with i oho ohms, there is definitely a fault current. The relay H, on the other hand, responds perfectly at all times in parallel to the resistors Wil to Wio.

When relay H responds, an excitation circuit for relay S is prepared by switching contact 34h. The relay V is not energized when the switching mechanism Sp is set to position i9 when relay I drops through contact 2.1 i, since contact 34h has been switched. Contact 33h is opened. A current impulse is therefore not sent out in position i9 of the impulse transmitter Sp when it is occupied via the access Co. The relay B talks about the contacts 5 c, 1o 1a, 7 i in position 1 9 of the impulse transmitter Sp again, so-effected an energization of the relay I above earth, battery resistance Will, shifting spb, contacts i9, 14 b , Winding II of relay J, contacts 24p, ioa, 5c, earth. The relay J switches on the rotary magnet Dsp via contact igi, whereupon the selector Sp moves to position 20. The relay H, whose excitation circuit is interrupted in position 20 via the switch arm spa, drops out.

The selector Sp is now switched on in the manner already described by the interplay of the relays B and J to position 23. In this, after relays B and J have dropped out, the following circuit is established for the excitation of relay V: Earth, battery, contact 9 c, relay V, contact 2i i, switch arm spc, contact 23 in the contact bank of switch arm spc, contact 341t, Earth. The relay V responds, opens the short circuit for the winding I of the relay B through contact 30v, so that the current impulse ratio required for the transmission of current impulses is present, and prepares the outgoing current impulse circuit by moving the contact 29v. The contact 32 e applies control voltage to the b-wire. If the selector Sp 'gets into position 24 by the response of the relays B and J, the first rush of the third rush series to be emitted by the rush transmitter Sp is made to emit by closing the contact i8i. The impulse transmitter Sp is now switched step by step by the play of the relays B and J already described, with the contact 1 8 i sending a current impulse with each step of the selector Sp.

If the switching arm spa reaches the position 33, the relay H responds via its winding 1 parallel to the resistor Wil via the occupied access Coo. The relay V drops after setting the selector Sp in position 33 when the contact toi opens. A renewed excitation of the relay B does not take place, since when the contact 34h is switched over the relay S is excited and the relay A is excited via the winding III via contact 36s. The excitation circuit for relay S runs from earth via contact 34h, winding of relay S; Contact 33 in the contact bank of the switching arm spb, resistance Will to the battery, earth, the relay A is energized in the following circuit: earth, contacts i9i, 36s, winding III of relay A, contact 8c, battery, earth. By switching the contact ioa, a renewed excitation of the relay B when the contact r7 i closes is prevented. By moving the contact iia, the line Lb2 is also switched through to the line Lb. > But contact 37 s the line Lb has been switched through. Contact 35s is opened and switches off the Frz character. The calling station has now been connected to the desired location via the line La-Lb and the line Lag Lb.

If the selected position is occupied, the subscriber receives the busy signal after he has received the signal Frz during the working hours of the impulse transmitter Sp, whereupon he initiates the release of the thawed connection by hanging up his receiver. Here, the circuit of the relay PA is interrupted in any known manner, so that the relays C and H also drop out. - By opening the contact 6 c, the test circuit for the relay P of the selector W2 is interrupted, so that the downstream voters can also take their rest position. The voter W2 remains in the position reached. The relay A is de-energized by opening the contact 8c, the relay S by opening the contact 341a. The following circuit is created for the excitation of relay B: earth, contact 5 c, switch arm spd of selector Sp in position 33 contact ioa or 24p, contact 17i, windings I and II of relay B, battery, earth. The relay B responds and causes the battery to be applied to the winding II of the relay J via the contacts 14b and 3314, and earth is connected to the other terminal via contact 5c, Schaltarmspd, contacts ioa and 24p, respectively. The relay J responds and excites the rotary magnet Dsp in the following circuit: earth, contact igi, i2 a, 15 b, rotary magnet Dsp, battery; Earth. The selector Sp arrives at position 34. When this is reached, the contact i dsp is opened, whereby the relay J is de-energized when the relay B drops out. A renewed energization of the relays B and J then switches the selector to position o, in which the earth serving at contact 5c to energize the relays B and J is switched off. The impulse transmitter Sp has then assumed its rest position and is available for establishing new connections.

If the impulse transmitter Sp is occupied via an access other than the Coo access, after the de-digits i and ö have been sent out, the impulse transmitter Sp will also send out the number i when it reaches position 19 and then send out an access corresponding to the occupied access Surge series. If, for example, the impulse transmitter Sp is occupied via the access C, 15, the relays P_A and I% respond in the manner already described. After setting the lt >> selector, the impulse transmitter begins to work on a free line and sends the number i when it is set in position 2 and the number o when positions 6 to 15 are exceeded. thus the relay V is energized as soon as the relays B and J have dropped out. The excitation circuit for relay L 'runs from earth via battery, contact 9 c, relay f%, contact 21 i, switch arm spc, contact i9 of the contact bank of the switch arm spc to contact 3411, earth. The relay V responds and prepares the Sirom surge circuit via the wire La through contact 29 v. before. Contact 32v applies control voltage to wire Lb_. The contact 3o v opens the short circuit via the winding I of the relay B, so that a current surge ratio for the relays B and J which is favorable for the transmission of current surges is established. If relay B is excited by closing contact 171, when relay J responds via contact 14 b, a current surge is emitted by closing contact iSi. The selector Sp arrives at position 2o, in which, after relays B and J have dropped out, relay 1l is de-energized by opening contact toi. The impulse transmitter, Sp now runs slowly up to position 23. In this position, after relays B and J have dropped out, relay V is energized in the following circuit in the manner already described in the previous connection: earth, contact 34 lt, contact 23 in the Contact bank of the switching arm spe, switching arm spc, contact 2 i i, relay V, contact 9 c, battery, earth. Relay Ir lifts the short circuit for winding I of relay B via contact 30v and prepares the outgoing surge circuit through contact 29v. A holding circuit for relay h for the response time of relay I is established via contact 31v and control voltage is applied to wire L b2 via contact 32V. The switching is now carried out in the manner already described when the connection was established for the first time! device of the impulse transmitter Sp, with each step of the selector a current impulse is transmitted via contact 18 i.

If the switching arm spa reaches the contact 28, which is connected to the occupied access Coi5, five current impulses have been transmitted. The relay H responds via its winding I in the following circuit: earth, switching means (not shown) on contact 3 pa, winding I of relay P: 4, switching arm cw of selector W, access C "5, contact 28 in the contact bank of switching arm spa , Switch arm spa, winding I of relay H, winding I of relay C, which according to the present conditions can expediently be assumed to be about 100 ohms, contact 4 c, resistor Wils, battery, earth. Relay H speaks parallel to the resistor As on and actuates the contacts 33h and 341c. By flipping the contact 341a, earth is switched off from the interconnected contacts 23 to 32 in the contact bank of the switching arm spc, so that the relay h is de-energized when the relay J drops out responds in the following circuit: earth, contact 34h, relay S, contact 28, switching arm spb, resistor joke, battery, earth. It actuates the contacts 35 s to 37 s. By closing the contact 36s, the winding III of the relay A i n energized in the following circuit: earth, contacts 19i, 36s, winding III of relay A, contact 8c, battery, earth. The relay A actuates its contacts and prevents the excitation of the relay B by switching the contact ioa after the relay J has dropped. The connection is switched through after the last series of current impulses consisting of five current impulses has been transmitted in the manner already described for the first connection establishment.

It is triggered by switching off the earth at the relay PA, whereupon the de-excitation of the relays A, C, P, S and H, which are excited in the impulse transmitter during a connection, is carried out. The resetting of the impulse transmitter Sp is also carried out in the manner described above by the interplay of the relays B and J with the rotary magnet Dsp.

Figures 2 and 3 show further embodiments of the invention, and in particular the training of the accesses of the scanning Derailleur. In FIG. Z, instead of resistors, rectifiers in the accesses used and in Fig.3 chain contacts, through which then a flawless Creation of an excitation circuit for the relay H when scanning the entrances is enabled when the occupied access is found.

If in Fig. 2, the selector W with its switching arm cw on a the accesses of the impulse transmitter Sp are set, an occupancy circuit comes up comes about, which is similar to the assignment circuit described in Fig. i. Will For example, if the access Co "is occupied, the following circuit is established: Earth, Release or switch-on switching means (not shown), relay PA, windings II and I, switch arm cw, contact 3 in the contact bank of the switch arm cw, line Col8, Rectifier GL3, winding I of relay C, switching arm spb of an impulse transmitter Sp, resistance Wi12, battery, earth. The relays PA speak in this circuit and C on. The relay C sets the contact q. c um, making about the resistance Wiis Battery is applied directly to winding I of relay C. The relay PA blocks the access found against other occupancy.

If another voter W, for example as a group voter or Line selector can be formed on one of the accesses Coo-Coii, for example set to access Cots, the test relay will respond Selector does not come about because at the junction point of the rectifier GLl-GLO blocking potential of the previously: set selector W is.

If, after one of the entrances has been occupied and the entrances blocked, the switching mechanism Sp is started in the manner described in FIG. An excitation of the winding I of the relay H via unoccupied entrances cannot take place, since the rectifiers located in the entrances only allow the current to pass in one direction and thus a response circuit for the relay H can only be established on the occupied entrance. The relay H can respond in parallel to the corresponding rectifier of this access only when the switching arm spa approaches the entrance, at which blocking potential is applied by closing the contact 3 pa, whereby it should be noted that the rectifiers have a certain resistance in their forward direction . When access Col8 is occupied, the following circuit is established when switching arm spa is set to contact 31: earth, triggering switch (not shown) on contact 3 pa, contact 3 pa, winding I of relay PA, switching arm cw, contact 3 in the contact bank of the switching arm cw , Contact 31 in the contact bank of the switch arm spa, winding I of relay H, winding I of relay C, contact 4. c, resistor Wils, battery, earth. The relay H responds in parallel to the rectifier GL3. The same switching operations are now carried out as are described when the relay H of FIG. I responds.

If, after setting a selector W to one of the entrances to the impulse transmitter Sp and executing the blocking, another selector W is set to one of the entrances, then, as already mentioned, the blocking circuit established by the response of the relay PA via contact 3 pa comes into effect, that the test relay PA of the second set selector W cannot respond. If, during the setting process of a second selector W, the switching arm spa of the switching mechanism Sp happens to come across the same entrance on which the second selector: is, but has not yet checked, the relay H via its winding I does not come into effect because it is via the high-resistance test relay of the second selector W set to the same access cannot check in parallel with the low-resistance blocking circuit of the selector W set first.

The arrangement of Figure 2 can therefore easily in place of the corresponding Arrangement of Fig. I occur.

3 shows a way in which chain contacts are arranged in the accesses instead of rectifiers or resistors. As such, the 'W selector shown in Fig. 3 corresponds to the shifting cw the selector W of FIG. I. The rush current transmitter Sp shown in FIG. 3 essentially also corresponds to the rush current transmitter Sp of FIG. Will the voter W ,. which can be configured as a group or line selector, set to one of the entrances, for example to access to contact 3, the following circuit is established via line 14: earth, switching means (not shown), windings II and I of relay P_4, switching arm cw of the selector W, contact 3 in the contact bank of the switching arm c7e "line L4, contact if of the relay F, winding I of the relay C, switching arm s r b of the impulse transmitter Sp, resistance lh'ils, battery, earth. The relays PA and C The contact 4c creates a holding circuit that maintains the blocking circuit independently of the actuation of the switching arm: rpb. By connecting all accesses to the impulse transmitter Sp in parallel, all accesses are blocked against occupancy by other checking voters TV.

If the current impulse transmitter Sp is started after the relay C has responded, a relay J is actuated at each step of the selector .Sp, similarly to the description of FIG. The relay J actuates its contacts and closes the contacts 2 i shown in FIG. 3. and 3 i. In the -i position of the impulse transmitter Sp, the following circuit for the winding I of the relay D is therefore established via the additional switching arm spe of the current impulse transmitter Sp: earth, contact 3 i., Switching arm spe, winding I of the relay D, battery, earth. The relay D responds and opens the contacts id, 2 d and 3d. The blocking circuit is maintained via the contact if, which has not yet been activated. Contact 2 i establishes a special holding circuit for winding I of relay C, which runs from earth via contact 2i, resistor IVi, 5, winding I of relay C, contact 4.c, resistor [Vi, 3, to the battery, earth . The test relay PA in question does not drop out due to the shunt temporarily established via the resistor LPi, 5. The relay H of the impulse transmitter Sp is not effective in position i because the contact id is open in position i of the selector Sp. If relay J drops out, relay D is de-energized when contact 3 i opens. When carrying out the second step by the impulse transmitter Sp, the relay E is energized via the winding I via the contact 2 on the switching arm Spe. This opens the contact ie, so that the relay H in position: 2 of the switch arm spa cannot respond. When the selector Sp reaches position 3, the relay F is excited via the winding I. The relay F actuates its contacts. The following response circuit for relay H is established via the occupied access L.,: Earth, battery, relay H, switch arm spa, contact 3 on switch arm spa, line Zn, contact 3 on switch arm cw, winding I of relay PA, contact 3 pa ., tripping switch means, not shown, earth. The relay H then takes the switching measures described when the relay H of FIG.

The voter Sp is triggered in the same way as this in the embodiment in FIG. i for the rush transmitter Sp became.

If the impulse transmitter Sp of FIG. 3 has been occupied, for example via the line L4, another selector ff, ' cannot check the access points of the impulse transmitter, since these are also connected to the blocking potential generated by closing the contact 3 pa due to their parallel connection . If another voter W nevertheless tries to check the line L ¢, for example via the access L2, after setting the shown selector W , the test relay of the later set voter W does not respond. If the impulse transmitter Sp accidentally hits contact i at this point, the following circuit is established: earth, battery, relay H, switch arm spa, contact i on switch arm spa, line L2, contact i, switch arm of the later set selector, not shown W, windings I and II of the relay PA of this selector, connecting means (not shown), earth. In this circuit, however, the test relay PA of the selector W set later does not respond, since the relay H has a high resistance. However, due to its design as a delay relay, the relay H also does not respond during the temporary application of the test relay PA. If the selector W is designed as a group selector, the response delay of the relay H must be so great that a searching! Group voter does not respond. If the selector W is designed as a line selector, the temporary switch-on time of the test relay PA must be shorter than the response time of the relay H.

If the voter W in Figs. I, 2 and 3 is designed as a group voter, so one of the entrances shown in the drawings is in one each Decade of the group selector, so that when setting the group selector, for example on decade 2 only the same entrances, for example entrances 2, different Impulse transmitters are reachable and in the 'Decade 3 the entrances 3 of these impulse transmitters are turned on.

It should also be noted that in the embodiment of FIG. 2, the winding l of the relay H can also be connected directly to the battery. In this In this case, however, the relay H would also have to be, as is the case with the execution of Fig. 3 is described, are formed with high resistance.

Claims (7)

PATEN TANSPRÜGIIE: i. Circuit arrangement for telephone systems with dialer operation, in which a tap automatically adjusts itself to one of these entrances via one of several entrances after the occupancy by an upstream voter, characterized in that both the occupancy process and the checking process of the tap to determine the access currently being used over the same wire (z. B. assignment wire C, 0) and in this wire switching means (z. B. Wi, GL, chain contact id) are, which block all other parallel accesses (Co "Cois) by the upstream Allow voters, and that the test relay (H) of the tap (Sp) to determine the access used is brought into connection with the switching means (Wi, GL, i d) located in the entrances, one after the other, so that it only opens when the tap is set the access used comes into effect. 2. Circuit arrangement according to claim i, characterized in that the blocking potential for blocking access after one of them has been occupied by the occupying voter (W) off is switched on in such a way that also to the other used in parallel lying accesses blocking potential lies. 3. Circuit arrangement according to claim i or 2, thereby. characterized in that the test relay (H) of the switching mechanism (Sp) is parallel switched on to the resistors or rectifiers in the accesses will. 4. Circuit arrangement according to claim i or 2, characterized in that the accesses for determining the access used by the switching mechanism (Sp) via chain contacts (i d, i e, i f..) In parallel 'to an occupancy relay (C) are, which by means of an auxiliary arm (spe) of the selector locally controlled relays (D, E, F) successively cancel the parallel connection at the entrance on which the selector (Sp) scanning the entrances is currently standing. 5. Circuit arrangement according to Claim 4, characterized in that the test relay (H) which detects the occupied identification line of the switching mechanism (Sp) is delayed in response or acts on devices operating with a delay in such a way that the response delay of these devices causes the temporary connection of the test switching means (PA, I and II) of the upstream voter bridged to an identification line of the tap (Sp) (Fig. 3). 6. Circuit arrangement according to claim 4 or 5, characterized in that the test relay (H) of the switching mechanism (Sp) is designed with such high resistance that a test relay (PA, I and II) of a further upstream selector (W) receives fault current (F ig . 3). 7. Circuit arrangement according to claim 4, characterized in that at each step of the switching mechanism (Sp) serving to determine the access used, a local holding circuit for the occupancy relay (C) of the switching mechanism comes about (contact 2i, Fig. 3). B. Circuit arrangement according to claim i or one of claims - to 7, characterized in that the switching mechanism (Sp) serving to determine a used access is automatically switched on after the occupancy and according to the occupied access when it is found by its test relay (H) becoming effective controls the emission of a certain number of series of impulses (Fig. i, 2 and 3). G. Circuit arrangement according to claim 8; characterized in that the test relay (H) of the switching mechanism (Sp) comes into effect in different positions (ig, 24 to 33) one after the other (Fig. i and 2). ok Circuit arrangement according to claim 8 or g, characterized in that the interrupter relays (J, B) of switching means (P, V) which work together with the switching magnet (Dsp) of the switching mechanism (Sp), which determine the respective setting of the switching mechanism or the respective state of the Characterize connection establishment, are controlled in such a way to determine the step speed of the switching mechanism that either two, one or none of the interrupter relays work attenuated (Fig. I).