DE908989C - Circuit arrangement for monitoring control currents, preferably of current impulses used for billing charges in telephone systems - Google Patents

Description

The invention relates to a circuit arrangement for monitoring control current surges, preferably of charging power surges in telephone systems. she is characterized in that switching means influenced by a temporary incentive for the initiation of the impulse transmission by repeating the stimulus in the rhythm of one after the other emitted current surges, preferably

ίο for charging a calling connection point serving current surges, are kept actuated, the within this rhythm Elapsing stimulus-free time by influencing the switching means during this period of maintenance Delay devices is bridged, which are only effective for a time that does not exceed this time or that does not exceed this time slightly. the The arrangement according to the invention offers the possibility, for example, when the emitted current surges serve to charge calling connection points, errors in the corresponding control circuits to determine and, if necessary, to signal.

In Figs. 1 and 2, an embodiment is shown to explain the invention, namely FIG. 1 shows a schematic representation of a z. B. accessible by a calling subscriber connecting line VL with a reversing dial UW used to establish the desired connection and one of these connec-

Extension line associated switch-on selector AW, via which a free zoner having the features of the invention is made available for the recording of charges when a connection is established.

Fig. 2 shows one of these zoners, e.g. B. VZ ₁ , in a detailed representation. The pulse generator PG which is required for this and which is common to a plurality of zoners is shown schematically in FIG. 2.

Achieved z. B. a not shown calling subscriber the connecting line VL of Fig. Τ, the reversing selector UlV (switching arms ι ... 5) is initially set. that his switching arm ι reaches a free line which leads to a number current surge receiver, not shown. In addition, in a way that is not of interest here, a switch-on selector AW searches for a free \ ^{r eroner, e.g.} B the zoner VZ ₁ shown in FIG. 2 . In the rest position of the zoner VZ ₁ , the relay R is energized via -, winding I of the relay R. Head contact 1 k _{v of} the selector W ₁ , contact 2 J _{2 of} the rotary magnet D ¹ HK _{2 of} the selector FF ₂ , head contact 3 &., Des Selector W ₂ , contact 4 a, winding II of the relay Y, contacts 5 c, 6if, J so, Sp, gal. Earth. Relay Y does not respond in this circuit. A common pulse generator PG is provided for several or all: Zoners. This consists, for example, of a motor-driven shaft on which a number of cam disks are attached for making contact. Through this contact, voltage pulses are given from the voltage source Sp in a certain rhythm. The contact of the individual X-cam disks is shown schematically in FIG. 2 by the progressive movement of a contact bridge B ₁ and a contact bridge B ₂ . During one revolution of the pulse generator PG z. B. the bridge .O ₁ is moved so that one after the other a voltage pulse Ps (synchronization pulse), a voltage pulse Pf (incremental pulse) and successively voltage pulses Pn ₁ , Pn ₉ , Pn ₃ (zoning pulses of the near zone NZ), a voltage pulse Pf (incremental pulse), one after the other voltage pulses PI ₁ , -PI ₂ . PI _: $ (zoning pulse of the far zone FZ ₁ ), a pulse Pf (stepping pulse) and successively voltage pulses PII ₁ , PII ₂ , PH ₃ (zoning pulses of the far zone PZ ₁₁ ), a voltage pulse Pf (stepping pulse) and one after the other voltage pulses PIII ₁ , PIII ₂ , PIII ₃ (Verzonungspulse the far zone FZuj), a voltage pulse Pf (Fort switching pulse; etc. and finally a voltage pulse Pf (Fort switching pulse) and a pulse (at the end as Nichtverzonungspuls pseudo zone XVZ) become effective each time the bridge B ₁ voltage pulses (eg. B. Ph ₁ ... Pn ₃ , Pl ₁ ... Pl ₃ , PII ₁ ... PII _3, etc .; allows the different zones to become effective as zoning pulses, the bridge B _{2 makes voltage pulses P 1} in a corresponding rhythm, P ₂ and P ₃ (main Office pulses) effectively so that therefore the bridge B can, ₂ during one rotation of the pulse generator PG repeatedly voltage coil P ₁ ... P occur. ₃ between the voltage pulses P ₂ and P ₃ each time or a voltage pulse Pus (Reversing pulse) effective.

If the zoner FZ ₁ , as already mentioned, is occupied by the switch-on selector AW (Fig. 1), then, since the contact is closed, the relay C is energized via -, Wi ₁ , contact ι or, winding I des Relay C, wire 1, switch arm α of the switch-on selector AW, contact at. Earth. By closing the contact nc, a holding circuit is closed for the winding I of the relay C. As long as the head contact 12 ^ _{1 of} the selector W _{1 is} closed, the relay C is delayed by short-circuiting its winding II. The relay P. holds itself after opening the contact 5 c via its winding II and the contacts 25 r and 26 t ". Since the counter switch Z is in the rest position and its rotary magnet Ds is not energized, the relay F is excited via - ·, Winding I of the relay 1 ", wire 5, switching arm b of the switch-on selector; AW, contact dz, earth.

j If the calling subscriber first selects the identifier 53 for the desired connection setup by sending out two series of impulses, then, since the contact nsi is initially actuated five times ^{in some way,!} winding I of relay A energized five times over -, winding I of relay A, contact 41 al. Wire 2, switch arm d of the switch-on selector AW, contact nsi, earth. During this series of impulses, winding I of relay V is excited via -, winding I of relay V, contacts 13 a, 14 c, earth. The relay V is delayed by short-circuiting its winding II via the contact 15z '. According to the series of current impulses consisting of five current impulses, the lifting magnet Hw _{1 of} the selector W _{1 is} influenced by -, Hw ₁ , contacts i6r, iju, i8c, 19c, 6st, 7 so, & p, gal, earth. The switching arms UW ₁ ... CW ₁ and the decade contact Cf ^ w ₁ are raised to the fifth decade. If relays A and V are de-energized again after the end of the series of impulses and consequently contacts 2OO and 21 ν are closed, relay US is excited via -, winding I of relay US, contacts 20 a, 2 \ v, decade contact dkw _t on contact 5 , Earth. The relay US is located with its winding II via the contacts 22 us and 23 c in a holding circuit. By closing the 24 us contact, an indicator for reversing the reversing selector UW to the desired direction is given via wire 3. Since the selector W shown in FIG. B. is adjusted by one step with each series of impulses, a circuit for the relay U ₁ is now established via - ·, JJ ₁ , selector iF in position 1, switching arm c of the switch-on selector AW, wire 3, contact 24 us, earth. By moving the contact U ₁ , the switching arm 1 of the reversing selector UlV is switched off and the switching arm 2 is switched on. The reversing selector UW is now looking for a free line with a downstream number surge receiver via this switching arm. The relay R (Fig. 2) is after the contact 27 ν at the end of the current surge series

and after lifting the selector W ₁ the head contact 28 ^ _{1 is} closed, brought to de-excitation by short-circuiting its winding II. The reversal takes place through the decade contact (IkW _{1 of} the selector W ₁ ; the selector W ₁ is later also used to determine the zone using its switching arm bw _v

The next series of current impulses, consisting of three current impulses, influences the rotary magnet DW _{1 of} the selector W ₁ via -, Dw ₁ , contacts 29? -, iyu, 18a, ige, 6st, 7 zo, 8 p, gal , Earth. The relay V is energized again and held during the series of impulses. The switching arms OW ₁ . .. Cw ₁ of the selector W ₁ arrive in the fifth decade of the contact 3. If de-energized after this impulse series, the relay V after deenergization of the relay A, the relay E and U to about speak -, H ^ i _3,

ao shaft contact 30W ₂ of selector W ₂ , winding I of relay U, relay E, contact 31p, shaft contact 32W ₁ of selector W ₁ , contact 33 v, head contact 34 & ₂ of selector W ₂ , contacts 35 x, 30Ji, 37 c, Earth. After the contact 39 e is closed, the relay St is energized via -, Wi ₁ , contact 38 s, windings II and I of the relay St, contacts 39 e, switching arm bw _{x of} the selector W ₁ on contact 3 in decade 5, earth . After the contact 100 Ji is closed, the windings I and II of the relay St are placed in a holding circuit -, Wi _it windings II and I of the relay St, contacts 100 st, 96 c, earth. Since the relay Y, as already mentioned, is excited via its winding I and the contact dz of the rotary magnet Dz of the counter switch Z (FIG. 1), heating of the thermal relay Th begins after the contact 49 Ji is closed; this does not yet initiate a switching process. When contact 30Ji is opened, relays E and U are de-excited.

By opening the contact 6 st , further influencing of the selector W ₁ and W _{2 is} prevented during the further impulse transmission to complete the desired connection. By closing the contact 40 st excitation of the relay .9 via its winding I is prepared. This excitation takes place as soon as the pulse generator PG allows the voltage pulse Ps (synchronization pulse) to become effective at the start of a new cycle. After the excitation, the relay S holds on its winding II and the contacts 42 s and 14 c. By closing the contact 43Ji, the grid G _{1 of} the discharge tube Rö is connected to the switching arm Cw ₁ and by closing the contact 44J, the grid G _{2 of} the discharge tube Rö is connected to the line leading to the voltage pulse Pn _1. After opening the contact 38 j, the relay St (windings I and II) is held in the charging circuit of the capacitor Ko _{2 for} a while. The grids G ₁ and G _{2 of} the discharge tube Rö are biased by a suitable choice of the voltage - Ug so that the discharge tube Rö becomes permeable when voltage pulses occur simultaneously at the grids G ₁ and G _2.

If, after the transmission of the voltage pulse Pj, the bridge B _{1 is} initially in a position such that the voltage pulse Pf (incremental pulse) becomes effective, the relay ZO is excited because the contacts 45 st, 46 p and 47 j are closed . By temporarily closing the contact 51 zo , the rotary magnet Dz of the counter switch Z is excited via the wire 4 and the switching arm e of the switch-on selector AW , so that the counter switch Z executes a step. When contact dz is opened, relay Y is temporarily de-energized and thermal relay Th is temporarily switched off. In addition, the winding III of the relay St (contacts 49.fi and 483;) is influenced during this time, so that the relay St, whose winding I is short-circuited to delay via the contact 113 J, during the sequence of incremental pulses Pf, if the Counting switch Z works, is held. If, during the further rotation of the pulse generator PG, the bridge B _{1 is} in such a position that the voltage surge Pn ₁ (near zone NZ) becomes effective, this voltage pulse Pn ₁ reaches the grids G ₁ and G _{2 of} the discharge tube Rö at the same time. The discharge tube Rö ignites, so that the relay P responds in the anode circuit via the discharge tube Rö, winding I of the relay P, contacts 54J, 55 c /, 26 c, earth. By closing the contact 58 ^ the relay P with its winding II is in a holding circuit -, winding II of the relay P, contacts 56 ", 57 e, 58 p, 55 al, 26 c, earth. When the contact 58 ^ is actuated, the anode circuit of the discharge tube Rö is opened, so that the discharge tube Rö is extinguished and the winding I of the relay P is switched off. By opening the contact 8 p , further influencing of the rotary magnet Dz of the counter switch Z via the wire 4 is prevented. Relay Y is again excited via contact dz. Since the relay St (contact 48 V open) is now de-energized, there is no further heating of the ¹ OS thermal relay Th because the contact 49 Ji is open. B. over the counting wire z, since the contacts of the counter switch Z (switching arm α) are wired according to the fee to be charged for the individual connections in some way not of interest here with a counter current impulse transmitter ZS , so that according to this wiring and the position of the counter switch Z. are (arm A) Zählstromstöße on the counting wheels ζ for affecting the counter of the calling subscriber provided.

At the end of the conversation the Verzoner FZ ₁ is released, since the holding circuit for the coil of the relay I C through the wire 1 at the contact with is interrupted. The relay Y is de-energized by switching off its winding I. By opening the c-contacts, the relays of the zoner VZ ₁ , which have been energized up to now, are switched off. By closing the contact 5 c , the rotary magnet Dw _{1 of} the selector W _{1 is} in series with the winding II

of relay Y excited via -, Dw ₁ , head contact 64 ^ ₁ of selector W ₁ , contact 2 d ₂ of rotary magnet Dw ₂ , head contact 3 k ₂ of selector W ₂ , contact 4a, winding II of relay Y, contacts 5 c, 6 st, 7 zo, 8p, gal.Earth . By closing the contact 60 y , since the contact 61 c is closed, the relay A is excited via its winding II. The contact 4 α interrupts the excitation of the rotary magnet Dw _{1 of} the selector W ₁ and the relay Y, so that the winding II of the relay A is de-energized again by opening the contact 60 y. The interplay is repeated until the head contact 64 ^ _{1 is} opened in the rest position of the selector W _1. Then, after the contact 1 ^ _{1 is closed,} the winding I of the relay R is influenced, so that the relay R is excited again when the \ ^ erzoners FZ _{1 is in the rest position.}

If the calling subscriber selects the corresponding one to set up another connection

ao identifier 279, simultaneously with the number surge receivers that can be reached one after the other via the switching arm 1 of the reversing selector UW, the switching arms of the selector W ₁ according to the explanation already given by the series of current surges consisting of two current surges for the second decade and in this decade by the seven current surges existing series of current impulses set to contact 7. After the relay V is de-energized, the relays E and U respond again.

The relays US and St are not yet energized, because neither the decade contact dkw _x nor the switching arm bw _{t will} produce an excitation circuit. The third series of current impulses, consisting of nine current impulses, raises the switching arms of the selector W ₂ and the decade contact dkw _{2 of} the selector W ₂ to the ninth decade. The lifting magnet Hw _{2 of} the selector W ₉ is namely excited via -, Hw ₂ , 65 e, 66 χι, \ 8a, ige, 6 st, 720, 8 p, gal, earth. After this influencing of the lifting magnet Hw ₂ , the switching arms aw ₂ ... cw _{2 of} the selector W _{2 are} before the ninth decade and the decade contact dkw _{2 is} on contact 9.If the voltage pulse Pus comes into effect while the pulse generator PG is circulating, it takes effect to the grids G ₁ and G _{2 of} the discharge tube Rö, namely to the grid G _{1 via the switching arm OKi 1} standing on the contact 7 in the second decade, the contacts 70 z /, 71a, 7211s, 73 e, shaft contact 74W ₂ des Voter W ₂ ,

So contacts 75.fi and 52 p, as well as to the grid G ₂ via the decade contact dkw _o on contact 9 and the contacts 76i, 53 ^. As a result, the discharge tube Rö is permeable, so that the relay P in the anode circuit responds via the discharge tube Rö, winding I of the relay P, contacts 115 .r, 7711s, 80s, 55a /, 26c, earth. After the contact 58 p is closed, the relay US is energized -, winding II of the relay US, contacts 81 e, 58p, SSaI, 26 c, earth. By closing the contact 22 us , the relay US places itself with its winding II in a hold circuit. By closing the contact 24ns , the relay U ₃ is given via the wire 3 to reverse the reversing selector UW in the direction indicated. The selector W is namely after the emission of the third series of impulses on the contact 3. By switching the contact Zi ₃ , a free line through the switching arm 4 is now sought. The change of direction takes place with the assistance of the zone detection selectors W ₁ (switching arm CW ₁ ) and W ₂ (decade contact dkw ₂ ) . The discharge tube Rö, which is also used for the subsequent zone determination, is involved in this process. Now the relay E and the winding I of the relay U are switched off, which were initially influenced during the series of nine current surges via -, Wi ₃ , shaft contact 30W ₂ , winding I of the relay U, relay E ₁ contacts 67 e, o8v , 35 x, 36 st, 37c, earth and after the end of the series of impulses were influenced further for some time in the charging circuit of the capacitor Ko ₁ via the resistor Wi ₅ . The capacitor Ko ₁ is in the meantime charged. The relay U continues with its winding II over -, winding II of the relay U, contacts 69 ", 36 ^ 37 c, earth. The discharge tube Rö has meanwhile been extinguished when the contact 58 £ is actuated, and at the same time the relay P has been switched off. After contact 820 is closed as a result of excessive excitation of relay E , the voltage pulse P _{1 that is} effective when the pulse generator PG circulates comes via the switching arm CW ₁ of selector W ₁ , which is on contact 7 for the second decade, contact 82 e, shaft ^{contact 74 1} W _{2 of} the selector W ₂ and the contacts 75 st, 52p to the grid G _{1 of} the discharge tube Rö and at the same time to the grid G ₂ via the decade contact dkw _{2 of} the selector W ₂ on the contact 9 and the contacts 76 j and 53 g . The discharge tube Ro ignites again, so that the relay P responds again via its winding I. After closing of the contact 86 p excitation of the relay X comes about - relay X, 83 g, 84 ", 85 ^, 86 p, 87 al, 88 c, earth.. The relay X is held by its contact 81 x. By opening the contact 115.tr the decision i 5 ° charge tube Ro is cleared and the relay P energizes. As a result, the rotary magnet DW _{2 of} the selector W ₂ receives a current surge via -, Dw ₂ , winding III of the relay U, 89 e, 66u, gox, 19c, 6st, 7Z0, 8p, gal, earth. Since the shaft contact 92W _{2 is} closed after the "" switching arms of the selector W _{2 have been} screwed in, the relay Q is energized via -, Wi ₃ , shaft contact 92W ₂ , relay Q, contact 88c, earth. In addition, after the contacts 95 g and 99 g have been closed, the relay St speaks to over -, Wi _v contact 38 s, windings II and I of the relay St, contacts ggq, g7 x, 95 g, 96 c, earth. By pressing the contact 93 g, the winding II of the relay U is switched off and the relay U is de-energized. After closing the Koniao taktes40ii, the relay S is excited via its winding I when the voltage pulse Ps (synchronization pulse) becomes effective at the beginning of a cycle of the pulse generator PG. The relay S holds after closing the contact 42 j over its winding II while

the relay St is initially held in the charging circuit of the capacitor Ko _{2 for} a while. During the further circulation of the pulse generator PG of the voltage pulse Pf (Fort switching pulse) for excitation of the relay ZO is twice effective so that as the rotary magnet Ds is moved away of the counter switch Z by two steps by the two-time closing of the contact 51st The relay Y is switched off twice by opening the contact dz , i.e. the heating of the thermal relay Th is interrupted twice. The relay St is held intermittently via its winding III (contacts 49.fi and 48 y). If then during the further rotation of the pulse generator PG the voltage pulse P ₁ via the switching arm cw _v standing on the contact 7 in the decade 2, the contacts 43.fi and S ² P ^{on the} grid G ₁ effective and at the same time also influences the voltage pulse FI ₁ of Far zone FZ ₁ via the switching arm aw _{2 of} the selector W ₂ standing on contact 1 in decade 9 and via the contacts 101 x, \ O2S, 103 u and 104 g the grid G _{2 of} the discharge tube Rö, so the anode circuit comes through the above-described grid influence for the third time ignited discharge tube - ^ »again the relay P via its winding I for excitation and its winding II via the contacts 56U, 57e, 5 & p, 55a / and 26c in a holding circuit. By opening the contact 8 p , further influencing of the rotary magnet Ds of the counter switch Z via the wire 4 is prevented. In addition, further series of numbered current impulses cannot influence the rotary magnet Dw _{2 of} the selector W _2. The discharge tube is Ro 58p on actuation of the contact deleted. The relay St is de-energized because the capacitor Ko ₂ , in the charging circuit of which it was held for 38 s after the contact opened, is charged and the circuit for the winding III at the contact 48 y is interrupted for a long time. The thermal relay Th is switched off by opening contact 49.fi. The participating earlier in the reversal voters W ₁ and W ₂ now served to the zone detection, namely the shifting CW ₁ and selector W ₂ was the shifting aw ₂ used by voters _W1. The counting current impulse is sent again via wire s according to the setting of counter switch Z on contact 2.

Should the subscriber establishing the connection continue dialing the number after choosing the series of current impulses consisting of nine current impulses, after the relay E de-energizes and before, for example, the relay St has become excited, the following series of current impulses will affect the rotary magnet Dw _{2 of} the selector W ₂ and screw the switching arms aw ₂ .. .cw ₂ in the ninth decade onto a contact corresponding to the following series of current impulses. Since only contact 1, which can be reached by switching arm aw ₂ in the ninth decade, is zoned, there would be no billing of charges for the connection established in this way. In order to prevent further connection establishment in this case, the contacts 2 ... ο in the decade 9 reached are connected to each other by additional wiring according to the wiring for the zone detection and to the segment NVZ (pseudo zone) of the pulse generator PG switched on to activate a non-zoning pulse. In this case the voltage pulse P ₁ on the response of the relay St via the switching arm Cw ₁ of the selector W _1, which is in the second decade on the contact 7, effective on the grid G _1, and concurrently occurring over the segment NPCs voltage pulse (NPCs ) effective on the grid G ₂ after, in this case, for. For example, the voltage pulse Pf is i5mal become effective as Fort switching pulse for influencing the relay ZO and consequently over the contact 51 so the rotary magnet Ds of the counter switch Z I5mal has been affected, so the discharge tube Ro is light and by this relay P attracted a further influencing of the rotary magnet Ds of the counter switch Z (opening of the contact Sp) . In position 15 of the counter switch Z (arm b) (relay AR energized in a manner not shown), a release (contact ar) of the connection path established up to now is initiated. The same processes can occur if other series of current impulses are selected as identification if this results in selector settings for which zoning is not possible. So z. B. when choosing the marking 2781 ... 2780; here the switching arm aw _{2 of} the selector W ₂ reaches the interconnected contacts in decade 8 and thus in a position via which the voltage pulse NVZ again becomes effective as a non- _{zoning pulse on grid G 2.} In this case too, after the counter switch Z has been advanced to position 15, the connection is triggered. All identifications that are not zoned are evaluated, so to speak, by forming a pseudo-zone (NVZ) in the zoner FZ _{1 in} such a way that the set number surge receiver is triggered. The same processes (triggering) occur if the wiring of the customs clearance has cold soldering points or is otherwise interrupted in some way.

The triggering of the zoner FZ ₁ with such a setting of the selectors W ₁ and W _{2 also} takes place in that first the relay C is de-energized and all other relays that are still energized are switched off by the corresponding c-contacts. Then the selector W ₂ is first triggered by influencing the rotary magnet Dw ₂ in interplay with the relays Y and A , since the head contact 59 £ _{2 of} the selector W _{2 is} closed; After the selector W _{2 has returned} to the rest position, since the head contact ^ k _{2 of} the selector W ₂ and also _{the head contact 64 ^ 1 of} the selector W _{1 is} closed, the rotary magnet Dw ₁ also interacts with the relays Y and A. de-energized to bring the voter W ₁ to the rest position. As soon as both voters have returned to the rest position, the relay R comes over his

Winding I again in the rest position of the zoner VZ ₁ for excitation.

If the calling subscriber selects the code 8592, the switching arms of the selector W ₁ in the eighth decade on the contact 5 and the shaharms of the selector W ₉ in the ninth decade are simultaneously with the number current impulse receivers reached one after the other via the switching arm 1 of the reversing selector UW Contact 2 set. The fourth series of current impulses, consisting of two impulses, influences the rotary magnet Dw, the selector W ₂ via - .Dw ₂ , winding III of the relay U, contacts 89t ', 66 u, 180, 19c, 6st, after the de-energization of the relay E 7 so, 8 p, gal, earth. After turning in the selector W ₂ , since the shaft contact 92 W _{2 is} closed, the relay Q is energized via -, Wi ₃ . Shaft _{contact 92W 2} , relay Q, contact 88 c, earth. The relay U remains energized for some time after the contact 93 q in the charging circuit of the capacitor Ko _{1 is closed.} Winding II of the relay U ₁ contacts 691 /, 93 g, Wi-, capacitor Ko ₁ , contacts 35- ^ 36 ^ f ₁ 37c, earth. If the voltage pulse Pus now occurs, it reaches the grids G ₁ and G _{2 of} the discharge tube Rö, namely to the grid G ₁ via the switching arm SiB _{1 of} the selector W ₁ , which is on the contact 5 in the decade 8, the Contacts yov, 71a, 72ns, shaft _{contact 105W 2 of} the selector W ₂ , contacts 75 ·>. ·., 52 p and to the grid G ₂ via the switching arm cw _ä , which is on contact 2 in decade 9, the contacts 106 u and 1045. The discharge tube Rö ignites, so that the relay P responds again via its winding I in the anode circuit of the discharge tube Rö. After the contact 58p closes , the relay US is energized -, winding II of the relay US, 107 q, 108 u, 57 e, $ 8p, 55 al, 2.6 c, earth. The changeover criterion (relay U _i via selector W ₁ on contact 4) is given by contact 24Mi via wire 3. By moving the contact H ₄ , the switching arm 5 of the reversing selector UW is made effective. By opening the contact 77 us , the relay P is deenergized and the discharge tube Rö is extinguished. If now, after the capacitor Ko _{1 has been} charged, the winding II of the relay U is also de-energized, that is to say the relay U is de-energized, the relay St speaks to via -. Wi ₁ , contact 38.?, Windings II and I of relay St, contacts 94 u, 95 q, g6c, earth. By closing the contact 40 st the winding I of the relay ^ is brought under the influence of the voltage pulse Ps (synchronization pulse j, so that the relay 5 responds at the beginning of a new cycle of the pulse generator PG . By closing the contact 42 s , the relay .9 with its winding II in a holding circuit. The maintenance of the excitation of the relay St takes place as already described. During the further cycle of the pulse generator PG the relay ZO is excited every time the voltage pulse Pf (incremental pulse) occurs and is caused by its contact

51 such an influencing of the rotary magnet Ds of the counter switch Z via wire 4. After switching four times, the voltage pulse P ₂ reaches the contacts 117 g, 43 Jf, again via the switching arm bw _p, which is on contact 5 in the decade cS.

52 p to the grid G ₁ and at the same time the voltage pulse PIII ₂ (FZi _n ) via the switching arm bw ₂ , which is on contact 2 in the ninth decade, the contacts 109 ^, 102s, 103 u, 1045 to the grid G ₂ of the discharge tube Rö. The discharge tube Rö ignites again and causes the winding I of the relay P to be excited in its anode circuit. By opening the contact 8 p , further influencing of the rotary magnet Ds of the counter switch Z via the wire 4 is prevented. This enables counting via wire 5 in accordance with the setting of counter switch Z (arm 0) on contact 3. P by closing of the contact 58, the relay P inserted with its winding II in a holding circuit, ^r w hile upon actuation of the contact 58 p is the winding of the relay P I switched off and the discharge tube Ro is cleared. In the connection case described above, the switching arms OW ₁ and cw ₂ were used for reversing and the switching arms bw ₁ and bw _{2 were} used for zone detection. The discharge tube Rom was repeatedly turned on. The release after the end of the call takes place in the manner already described.

If the calling subscriber selects the identifier 9400, through which, for example, a service line DL (FIG. 1) is reached, the dialers W ₁ and W _{2 are set} as in the connection case described above. The switching arms of voter W ₁ arrive in the ninth decade the contact 4 and the switching arms of voter W ₂ in the decade ο on the contact 0. Since after screwing of the selector shaft contact 92W ₂ has been closed W _2, is again the Relay Q energized. The relay U remains energized for some time after the contact 93 g has been closed in the charging circuit of the capacitor Ko _1. Is now after the charging of the capacitor Co _1, the winding II of the relay U de-energized, so the relay U-energized, thus saith the Relais St at about -.?, Wi _1, contact 38, windings II and I no relay St, Contacts 94 ", 95 q, 96 c, earth. By closing the contact 40 st , the winding I of the relay 6 "is brought under the influence of the voltage pulse Ps (synchronization pulse), so that the relay 5" responds at the beginning of a new cycle of the pulse generator PG. By closing the contact 42 s , the relay S places itself with its winding II in a hold circuit. The energization of the relay St is maintained as described above. During the further rotation of the pulse generator PG , the relay ZO is excited each time the voltage pulse Pf (incremental pulse) occurs and, by means of its contact 51, causes the rotary magnet Ds of the counter switch Z to be influenced via the wire 4. After six times

Continuation, the voltage pulse P ₃ reaches the grid G ₁ via the switching arm bw _v the contacts 117 ^ 43 · «, 52 p on the contact 4 in the decade 9, and at the same time the voltage pulse PV \ via the contact ο in the decade ο standing switch arm bw _v the contacts 109 ^ IO2S, 103 11, 104g to the grid G _{9 of} the discharge tube Rö. The discharge tube Ro ignites and causes the winding I of the relay P to be excited in its anode circuit. By opening the contact 8 p , further influencing of the rotary magnet Ds of the counter switch Z via the wire 4 is prevented. Since the switching arm b of the counter switch Z is on the contact 6, the relay U _{6 is} excited in some way that is not of interest here and causes the service line DL to be connected to the occupied connection line VL by switching the contact U _6. The processes in the zoner FZ ₁ are the same as previously described. The counting switch is therefore now used to reverse the direction of traffic, namely it is advanced by a number of current impulses determined by the directional identification of a series of current impulses otherwise used to record charges. Here, the discharge tube, which is switched on between the selectors W ₁ and W ₂ , acts like the zone detection.

If the calling subscriber selects the code 7523 to establish a different connection, the switching arms of the selector W ₁ on contact 5 in the seventh decade and through the code part 75 simultaneously with the number surge receivers reached one after the other via the switching arm 1 of the reversing selector UW Identification part 2}, the switching arms of the selector W _{2 set} to contact 3 in decade 2. Before the switching arms of the selector W _{2 are set} to contact 3 in the second decade, the reversing criterion is first applied. This Umsteuerkriterium is given if after selecting the item 2 of the decade contact dkw is operated in the decade 2. ₂ The relay E is held in the charging circuit of the capacitor Ko ₁ after the number 2 has been selected. Then the reversing pulse Pus occurs on grid G ₁ via switching arm aw ₁ of selector W ₁ on contact 5 in decade 7, contacts 70 z /, 71 a, yzus, 73 e, shaft contact 74W ₂ of selector W ₂ , 75 st, S ² P and at the same time on grid G ₂ via decade contact dkw ₂ of selector W ₂ in decade 2, contacts 76 j and 53 g. The discharge tube Ro ignites, so that the relay P responds and after the contact 58 ^ closes, the relay US is excited via its winding II. By closing the contact 24z «, the relay U ₃ is excited via the wire 3 (after three series of impulses the selector W is on the contact 3). The arm 4 of the UW reversing selector is looking for a free number current impulse receiver after switching the contact M _3. The relay US is in the meantime with its winding II via the contact 221 ″ in a holding circuit. When the contact 58/7 is actuated, the winding I of the relay P is switched off and the discharge tube Rö is extinguished. If the relay E is de-energized as a result of the completion of the charging of the capacitor Ko _{1 and consequently the rotary magnet Dw 2 of} the selector W _{2 is} actuated by the selection of the fourth digit 3, since the contact 89 t 'is closed, its switching arm arrives as before said, in the second decade on contact 3. Since after turning in the selector W _% the shaft contact 92W _{2 is} closed, the relay Q is excited via -, Wi ₃ , shaft contact 92W ₂ , relay Q, 88 c, earth. As in the previous example, the further switching operations proceed accordingly, the rotary magnet Ds of the counter switch Z being influenced three times (remote zone -FZ _{111) as in the previous example.} Then there is a simultaneous occurrence of the spam pulse P ₂ on the grid G ₁ and the voltage pulse PIII ₂ on the grid G ₂ , so that further influencing of the counter switch Z as in the connection case described above is prevented. The selector W ₁ and W ₂ and the discharge tube Rö were also used several times in this connection.

The circuit described also enables the zoning pulses and the progression of the counter switch Z as well as the respective ignition of the discharge tube Rö to be monitored. As can be seen from the circuit, the relay St holds when the counter switch Z z. B. as a result of the stepping pulse Pf occurring in the correct rhythm, i.e. continuous interruption of the circuit of the relay Y at contact ds, advances via its winding III (contacts 49 st and 483 ^ because the relay St is by short-circuiting its winding I via contact 113 j delayed. If a further switching pulse from or is the contact dz due to mechanical error of the count switch is not interrupted, so that the relay remains energized Y, the relay St falls off and switched on via its contact 114.fi the winding of the relay I Al a This relay gives an alarm. The same occurs if this tube does not ignite due to a faulty discharge tube Rö . After one cycle of the pulse generator PG , the sequence of the incremental pulses Pf is interrupted; after a longer period of time the synchronization pulse Ps occurs. The contact ds remains so longer than the rhythm of the incremental pulses Pf , closed, so the relay Y is energized longer, so that holding the Relay St is not possible via its winding III. Also in this case the relay Al comes to alarming for excitation (contact 114 ^).

If the relay St is energized to initiate the zone detection, there is no energization of the relay S z. B. as a result of a fault in the pulse generator PG (missing synchronization pulse Ps) , the relay St holds itself over -, Wi ₁ contact 38 s, windings II and I of the relay St, contacts 100 st, c, earth. Since the contact ds remains closed, i.e. the relay Y is energized, the thermal relay Th comes after a while via the contacts 49 Jf

and ii'6y. After closing the contact ii2th the relay Al responds through its winding II and sounds an alarm. By closing the contact al , the relay Al places itself with its winding II in a hold circuit; the thermal relay Th is switched off. The Zoner FZ _{1 can} be triggered by pressing the AL keys.

Claims (6)

PATENT CLAIMS: i. Circuit arrangement for monitoring control current surges, preferably of current surges used for billing purposes in telephone systems, characterized in that switching means (St), influenced by a temporary stimulus, for starting the current surge transmission by repeating the stimulus in the rhythm of the current surges sent out one after the other, preferably the one to charge a calling party Connection point serving current surges, are kept actuated, whereby the stimulus-free time elapsing within this rhythm is bridged by the influencing of the switching means during this time maintaining delay devices (StI with contact 113 ^), which are only effective for a time that does not or slightly exceeds this time. 2. Circuit arrangement according to claim i, characterized in that the repetition of the stimulus is caused by switching devices (F, Ds) which are actuated according to the transmitted current surges. 3. Circuit arrangement according to claim 2, characterized in that the number of Electricity surges by taking effect according to the required charge Switching elements is determined which further, this number of current surges exceeding Current impulses of a series of current impulses that are repeatedly transmitted with the same number of current impulses make ineffective for the charge. 4. Circuit arrangement according to claim 3, characterized in that when ineffective of the switching elements as a result of faults in the system, the series of current impulses that are repeatedly transmitted in their entirety becomes effective and repeats the incentive by means of the switching devices. 5. Circuit arrangement according to claim 4, characterized in that after the end of the entire series of current impulses up to the beginning of the repetition of the same, a larger break occurs compared to the break between the individual current surges, in which the delay devices become ineffective and the further influence of the switching means is canceled. 6. Circuit arrangement according to claim 5, characterized in that through the entire Current impulse series the switching devices Reach the state in which signaling takes place. 1 sheet of drawings © 5904 4.54