DE409411C - Circuit arrangement for telephone systems with dialer operation and automatic separation of the connection after a certain time - Google Patents

Description

GERMAN EMPIRE

ISSUED FEBRUARY 26, 1925

REICH PATENT OFFICE

PATENT LETTERING

- M 409411 CLASS 21 a GROUP 65

(S 60831 VIII [2ia ^s )

Siemens & Halske Akt-Ges. in Siemensstadt near Berlin *).

Circuit arrangement for telephone systems with dialer operation and automatic separation the connection after a certain time.

Patented in the German Empire on September 10, 1922.

In telephone systems with dialer operation is expected. Due to the length of the

it is known that a connection after Ab-! necessary connecting lines it is off

is disconnected over a period of time. The: economic reasons required the

The invention now relates to an adaptation of this number of these connecting lines so low

To keep arrangements to larger telephone networks with as humanly possible as the

several exchanges and various' cost of these interconnections, the economic

traffic zones. Strongly influence connections to the remote location of a plant.

th exchanges that are in another, It is therefore necessary to

Traffic zone, high-quality landings are to be used for as many connections as possible.

commitments for which an increased fee is to be used.

* < The patent seeker indicated that the inventors were:

Max Langer in Hermsdorf b. Berlin and Ernst Horn in Berlin.

According to the invention, therefore, by switching devices on the connecting devices or lines the connections established according to a determined by the value of the respective connection Time automatically separated. The maximum duration for low-order connections, i.e. H. for Connections to nearby exchanges is therefore longer than the maximum duration of high quality connections.

In the drawings, an embodiment of the invention is shown.

In Figs. 1 to 4, the current flows which come into question when making the various connections are shown. Let us first explain a connection between the subscriber Tn _{1 of} the sub-exchange UA I and the subscriber Tw _{0 of} the sub-exchange UA χ (Fig. 3), which is located in the same traffic zone.

When the caller calls Tn _1, the call relay R ₁ responds in a known manner of the preselector I. VW ₁ and causes the setting of this Vorwählersauf a free II. VW _1. If such a circuit is found, the following circuit is established: earth, battery, contact Ir ₁ , windings I and II of relay T ₁ , switching arm 2, contacts 3, 4f ₂ , relay R ₂ , earth. The relay T ₁ is in a known manner, the selection still, separating the contacts 5 and 6i _x the line relay R ₁ and switches on the contacts 7 and _8ί χ the speech wires a, b through. In the second selection II. VW the responsive relay _R2 closes before the circuit of the drive magnet D ₁ and prepares at the contact ior ₂ the excitation current for the test relay T ₂ at the contact Qr _2. The circuit of the drive magnet D ₁ runs as follows: earth, battery, contacts gr ₂ , 1 in, magnet D ₁ , contacts 12Ci ₁ , i3i ₂ , earth. If the second preselector II. VW ₁ finds a free transformer Ü and thus a free connection line VL ₁ leading to the main exchange HA , the following test circuit is established: earth, battery, contact ior ₂ , windings I and II of relay T ₂ , contact 14 «, switching arm 15, contact 16, wire 17, contact l & s, winding I of relay C ₁ , contact 19, W ₁ , earth. The relays T ₂ and C ₁ respond. The relay Tj interrupts the circuit for the drive magnet D ₁ at contact 13 *, switches the test and blocking wire from the first preselector I. VW ₁ to the transformer Ü at contact 15 by short-circuiting the high-resistance winding I of the relay T ₂ and disconnects at the same time the relay R ₂ from contact 4f ₂ . Furthermore. the speech wires are switched through to the feed bridge in the transformer Ü, which consists of the relays A ₁ and B ₁ , at contacts 20 and 2Ii ₂ . The latter two relays respond.

; In the transformer, the relay C ₁ closes its. Contact 22 and thereby prepares a holding circuit via its winding II. In addition, the impulse _{contact 25O 1 of} the relay ^ i _{1 is connected} to the wire 24 of the connecting line VL _{1 at contact 23C 1} . The responsive relay A ₁ opens the contact I clock 25%, via which the current surges for the J setting of the number surge receiver; are given, closes at contact 26 ^ ₁ ^: the relay V ₂ briefly with simultaneous Üffj tion of the short circuit across the winding II of the relay C ₁ at contact 27Ui ₁ and opens the impulse contact 28α _χ for the magnet D- ^,! of the tracking switchgear MS ₁ . The relay B ₁ opens, inter alia, its contact 29Z) ₁ , whereby the ^: short circuit around the winding I of the relay V ₁ '■ is canceled. The last-mentioned relay responds, opens its contacts 19, 30 and and closes its contacts 3 Iv ₁ and By closing the contact

the rotary magnet D _{2 of} the tracking switching mechanism MS _{1 is} switched on: earth, contacts 32 ^ ₁ , 34 » ₂ , switch arm 35, contact 36, magnet D ₂ (ms) , battery, earth. The switching arm 35 is set to the second contact 37 and thereby the following circuit is closed: earth, contacts 32 ^ ₁ , 34U ₂ , switching arm 35, contact 37, wire 38, winding 39 _{go of} the transformer, contact 40W ₂ , wire 41 of the connecting line FL ₁ , contacts 42C ₂ , 43 / ü-, relay F ₃ , winding I (Fig. 2), contact 44 of the tracking switching mechanism MS ₂ . Switching arm 45, resistor 46 ', battery, earth. The relay V ₃ responds, opens its contact 46W ₃ and closes its contacts 47V ₃ , 48F ₃ , 49F ₃ and 50F ₃ . Via contact 48 ^ ₃ , the rotary magnet D ₃ {ms *) of the tracking system MS _{2 is connected} to the _OK impulse contact 51 of a relay A ₂ , while the first group selector of the main office is occupied in the following circuit via contact 49W _3: Contact 49 ^ ₃ , relay C ₂ , resistor 52, contact 53S ₁ , wire 54, head contact 55 & of the first group selector I. GW ₁ (Fig. 3), winding I of relay B _s , winding I of relay C ₃ , battery, Earth. Relays C ₂ (Fig. 2) as well as Bg and C ₃ (Fig. 3) respond. The n ₀ relay C ₂ closes the contact 50c ₂ lying parallel to 49U ₃ , opens the contact 42C ₂ and closes the contacts 57 and 58C ₂ . At contact 57C ₂ , wire 41 is connected to wire 59 to the first group selector I. GW ₁ , while relay F _{3 is} kept energized via contact 58C ₂ , since its excitation circuit at contact 42C _{2 is} interrupted. The holding circuit runs as follows: earth, battery, resistor 46 ', switch arm 45, contact 44, winding I of relay F ₃ , wire 60, normally closed contact 61, switch arm 62, contact 58 ^ ₂ , earth.

Ira first group voter /. GW ₁ prepares the relay C ₃ by closing the contact (33C ₃ a holding circuit via its two windings I and II λόγ, which comes into effect as soon as the contact 55ε is interrupted by the first step of the group selector. The relay B ₃ switches to the Contacts 64 and 65Ib ₃ connect relay A ₃ to wire 66 and winding II of relay B ₃ to wire 59. The current impulses of the first series of impulses sent by the calling subscriber, in addition to the first group selector in the main office /. GiF ₁ also 'the tracking switching mechanism MS _t located in front of this group selector and the tracking switching mechanism MS _{1 are set} in the sub-center. It is assumed that with this connection, since the sub- exchange UAx is in the same traffic zone as the sub-exchange UA 1, only one count in If, for example, the first series of impulses consists of three impulses, then all three numbered impulse receivers (J. GW ₁ , MS ₁ , MS ₂ ) adjusted by three steps. The current pulses are added in a known manner by interrupting the line loop in the calling subscriber, so that drop at each current impulse, the relay A ₁ and B ₁ and the relay A ₁ 25O its Stromstoßkoniakte ₁ and 2Sa ₁ closes. The setting circuits for ■ the individual devices run as follows:

1. For the tracking switchgear MS ₁ in the sub-exchange: earth, contacts 32 ^ ₁ , 67 /, 28%, 36, magnet D ₂ , battery, earth.

2. For the surge receiving relays A ₂ (Fig. 2) and A ₃ (Fig. 3) in the main _{exchange: Earth, contacts 25 ^ 1} (Fig. 1), 23C ₁ , wire 24, from here once via relay A ₂ , Contact 50V ₃ , resistor 68, battery, earth and also via contact 6 (Ji ₃ J wire 66, contact 64O ₃ , relay A ₃ , battery, earth.

The relay A ₃ causes the setting of the I. GW ₁ to the third row of contacts in a known manner. The relay A ₂ (fig. 2) closes the electric circuit for the drive magnet D ₃ {ms ₂₎ as follows: earth contact 5ra _2J winding II of the relay F _3, contact 48 ^ _3, solenoid D ₃ (Hii "), battery , Earth. After the end of the series of current impulses, the switching arms 45 and 62 of the tracking switching mechanism MS ₂ are accordingly on the contacts 70 and 71. If the relay V _{3 has} dropped out, it can no longer be excited when the connection is further established. It should however in this case, notice that was immediately energized at the energization of the relay C ₂ and the relay U ₂ over its winding I as follows: earth contact J2c _v winding I of relays U _1, contact 73 / jr, drive magnet D ₄ of the Counting switch ZS ₂ , battery, earth. As a result of the high resistance of the winding I of U ₂ , the magnet D _{4 is} not excited. The relay U ₂ has

j its contact 74 ″ is opened and thereby prevents the magnet D ₃ [MS ₂ ) from being switched on after the relay V _{3 has dropped out} . When the first power surge is delivered

! the calling point and the opening of the contact 2Oe ₁ by the surge receiving relay A ₁ , the short circuit is canceled via the winding I of the relay V ₂ .

; The relay V ₂ can respond as a result and opens its contacts 34W ₂ and 4Ow _{2 .and}

, closes contact 74 ^ ₂ . As a result, the battery is connected to the wire 41 of the connecting line VL ₁ via the resistor 75 and through this the relay B ₃ (Fig. 3) is kept excited via its winding II as follows: Earth, battery, resistor _{75, contact 74 ^ 2} , wire 41 , Contact 57C ₂ , normally closed contact 76 and switching arm yy of the pickup switching mechanism ZS ₂ , branch point 78, contact 79 ^ ₃ , wire 59, contact 65O ₃ , winding II of relay B ₃ , earth. Relay B ₂ is also located at branch point 78 (Fig. 2) . But this is high resistance. So much current is drawn from it by winding II of relay B ₃ (Fig. 3) that it cannot respond. g ₀

The first group voter /. GW ₁ looks for a free connection line VL ₂ in a known manner, whereupon the connection is completed by setting the additional number current surge receivers (ζ. B.. II. GW ₁ and LfF _{4 shown in Fig. 3).}

It is assumed that the line selectors LfF _{4 are} equipped with a control switch and that the current impulse receiving relays A _{s unaB &} are switched off to excite the drive magnets after the series of current impulses have been emitted. It is also assumed that the position 13 is the communication division on the control switch, in which this _{arrives after notification of the requested subscriber Tm 5} and via which a feed relay Y for the subscriber Tw ₅ is switched on. When the control switch is in position 13, the battery is connected to wire 82 via a resistor 80 and control switch contact 81, which energizes relay B ₂ in Fig. 2 as follows (Fig. 3): Earth, battery, resistor 80, control switch contact 81 ( position 13), core 82, contact 83 and switch arm 84 of the second group selector ILGW _1, Kontakt85 /> _2, contact 86 and switching arm 87 n ₅ of the first group selector /. GfF ₁ , contact 88 />_1; Wire 59, contact 79J ₃ , branch point 78, relay B ₂ , earth. The relay B ₂ responds and causes the setting of the pickup switchgear ZS ₂ to the next contact by the circuit of the ,, - drive magnet. D ₄ . (zs //) as follows

is closed: Earth, breaker 89, contact 90 ^ ₂ , head contact 91 kss _{2 of} the pickup switch ZS ₂ , magnet D ₄ (.SUr ₂ ), battery, earth. The switching arm yy of ZS ₂ therefore reaches the contact 92. Further excitation of the magnet D ₄ is not possible, since the contact 91 kss ₂ is now open. The relay B _{2 also} connects at its contact 93 ^ ₂ earth to the relay A _s . In addition, the relay .S _{1 is connected} to the wire 54 via the contact 104 ^ _2. The relay S ₁ responds, opens its contact 53 ^ ₁ and closes its contacts 99J ₁ and 112S ₁ . The relay U _{2 is} kept energized via its winding II via the contact 112J _1.

Before continuing in the description of the further switching operations, the switching operations in the calling sub-exchange UA ι are explained. It has already been described that the first number stream series through which the first group selector /. GPF _{1 has been} set, and the tracking switchgear MS _{1 has been} adjusted, for example on contact 94. After this series of impulses has ended, relay U ₁ is energized as follows: Earth, contacts _{32 ^ 1} , 34 ^ ₂ , switch arm 35, contact 94 , Relay U ₁ , contacts 119 / and 12Oc ₁ , battery, earth. The relay U ₁ switches to a holding circuit via its contact 12Ui ₁ , but this can only be closed if connecting devices LW ₁ still running in the sub-office and accessible from the preselector IL VW ₁ are free. Only in this case is the contact 122g closed. The second series of rushes for setting the second group selector 27. GW ₁ causes the drive _{magnet D 2} (MS ₁ ) of the tracking switching mechanism MS ₁ to be activated in the same way as the first series of rushes. The switching arm 35 thereby reaches the contact 118, for example. After the relay V ₂ drops out as a result of a prolonged short-circuit at the contact 2Oa ₁ , the relay F is energized: earth, contacts 32 ^ ₁ , 342Λ ,, switching arm 35, contact 118, windings I and II of relay F, battery, earth. The relay F closes its contact 95 and thereby switches itself into a holding circuit which is dependent on _{the contact 96 ^ 1 of} the delay release relay V _1. In addition, the relay F opens the contact 67 /, so that further excitation of the rotary magnet D ₂ (Wi ₁ ) cannot take place through the further series of current impulses.

If after the end of the conversation the called subscriber hangs up Tn _s first, the control switch of the line selector LW _{1 is} in position 14. The circuit for the relay B ₂ (Fig. 2) remains in place, since the control switch, ters contact 81 (Fig. 3) is closed. If the calling subscriber Tn ₁ (Fig. I) also picks up his receiver, the relay A _{1 is} permanently de-energized. The contact 2Oa ₁ \ is therefore continuously opened and the contact 27O ₁ closed continuously. The winding II of the relay C ₁ is short-circuited, and the relay C ₁ drops out as a result. Among other things, it opens its contacts 22 and 23C ₁ and closes its contacts 97 and 98C ₁ . By opening the contact, contact 22C ₁ , the circuit is interrupted via the: winding I of the delay relay V _1. However, the following circuit is closed via contact 97C ₁ : earth, battery, winding II of relay V ₁ , contact 97C ₁ , wire 24, winding I of relay A ₂ , contact 93 & ₂ , earth. In this circuit, the relay V ₁ remains energized. The relay A ₂ addresses' and is a Zählstromstoß to Zählübertragungsrelais ZR in transformer U the exchange UAi ^au ^ following way: earth, contacts 99J _1, ΐοοα _2, relay HR, contact S7c _2, Core 41, contacts A-Ov _2, 98C ₁ , relay ZR, contact 3 Iv ₁ , earth. The relay Zi? 85 closes its contact loisr and applies there through the low resistance 102 parallel to the high resistance 103 to the wire 17 coming from the second preselector II. VW _1. The current, which via the counter Z on the first preselector /. VW ₁ flows ^,! is amplified to such an extent that the counter can respond and count the conversation. After the relay HR has been energized, the drive _{magnet D 4} (zs _w ) of the tapping switch ZS ₂ is energized as follows: earth, contacts 5Ie ₂ , loZfhr, magnet D ₄ (zs n), battery, earth. The relay HR short-circuits relay A ₂ at its contact io6hr, so that it drops out. The switching arm yy is adjusted by one step by the magnet D ₄ and reaches the contact 107. The relay B ₂ is now short-circuited, because at the branch point 78 there is ground via the contact 58C ₂ , the switching arm 62, the contacts 71 and 107 and the shift arm yy. The relay B ₂ drops out and opens the contacts 93 and 104. By opening the contact IO4 & ₂ , the holding circuit is interrupted via the relays C ₂ , S ₁ and C ₃ and the first group selector I. GW ₁ and the subordinate selector are triggered initiated in a known manner. Since the contact 93O _{2 has been} opened, the relay V ₁ in the transformer Ü loses its excitation and drops out.

The tracking switchgear MS ₁ and MS ₂ as well as the counting switch ZS _{2 are} triggered in the following way:

The relay V ₁ energizes the relays V ₂ and S after it has dropped out in the following way: earth, contact 33 ^ ₁ , winding II of relay V ₂ , head contact 107 ^ WJ _{1 of} the tracking switching mechanism

MS ₁ , winding II of relay S, battery, earth. Both relays 6 ¹ and V ₂ respond and close their contacts io8w ₂ and 109 s. This closes a circuit for the rotary magnet D ₂ (WiS ₁ ) as follows: Earth, contacts HOZZ ₁ , 1095, io8z> ₂ , 67 ' f, 28O ₁ , 36, magnet D ₂ , battery, earth. The magnet D ₂ responds, switches the follow-up switching mechanism on and short-circuits the relay F ₂ at its contact 11 id ₂ . The relay V ₂ drops out, opens its contact 108, whereby the magnet D ₂ drops out and the contact 111 opens. Now the relay F ₂ responds again, which closes the contact io8zz ₂ again. This game is repeated until the follow-up switching mechanism has reached its rest position, which is characterized in that the head contact _{ι OJkWiS 1 is} open. Renewed excitation of relay F ₂ after the rotation

ao magnet D ₂ is no longer possible.

The relay U ₂ in Fig. 2 was, as already mentioned, kept energized during the speech communication via a contact 112 of the relay ^ ₁ and its winding II. Since the relay S _{1 was} de-energized after the relay B ₂ dropped out, the relay U ₂ also loses its excitation and closes the following circuit for the magnet D ₃ (ms ”) : earth, battery, magnet D ₃ , contact 46 ^ ₃ , head contact 1 I2, kms _{2 of} the tracking switchgear MS ₂ , contact 74M ₂ , winding II of the relay HR, earth. The magnet D ₃ responds and closes the following circuit: earth, battery, winding II of relay U ₂ , contact 114Ci ₃ , winding III of relay HR, earth. The relay U ₂ opens the circuit for the magnet D ₃ at contact 74W ₂ , whereupon the magnet drops and the circuit for the relay U ₂ opens. This: game is repeated until the following switching mechanism MS _{2 reaches} its rest position, in which the contact 113 ^ mJ _{2 is} open.

Simultaneously with the tracking switchgear

MS ₂ , the switch ZS _{2 is also switched} to the rest position by _{closing the circuit for the drive magnet D t} (ss n) vfie : earth, battery, magnet D ₁ , head contact 11 $ kzs //, head contact 11 6kzs /, Contact 117K ₂ , relay HR, earth. The magnet D ₄ also closes a contact ΐΐ8ώ ₄ in the circuit of the winding II of the relay U ₂ , so that the | Switching the tapping switch on depends on the interplay between the magnet D ₄ and the relay U ₂ . The drive circuit for the magnet D ₄ is finally opened when the tapping switch reaches its rest position, in which the contact. 1 i $ kss [i is open.
Let us now consider the case that a connection is established with a subscriber who is connected to an exchange located in a different traffic zone. The exchanges for which a

! Zone counting comes into question, for example, via the eighth contact row of the first numbered surge receiver reached. The first group voter will therefore be on

, the eighth row of contacts is set, iri which he occupies a free connection line VL _5. The continuation of the connecting line VL _S is denoted _{by FL 6} in FIG. 3. At the meeting point of these two connecting lines (200, 201, 202) a connecting line VL _{9 is} connected, which comes from the contact sets of those first number impulse receivers (I. SW ₂ ) that are accessible to subscribers of the main exchange. Between contacts 203, 204 and 205 on the latter first

; Number surge receivers /. GW ₂ and the connection points 200, 201 and 202 is ■ the meter incremental device, which is only activated for connections originating from main office participants. This counter incremental device [MS ₃ , ZS /, ZS ₂ ) is therefore bypassed in the present connection. Simultaneously with the setting of the first group selector /. GW ₁ on the eighth contact group, the tracking switching

^: WeTkMS _{1 is set} to the eighth contact, which go is, for example, contact 118. After the relay F _{2 has} dropped out, the relay F is again excited, which prevents further excitation of the rotary magnet D ₂ by the further series of current impulses.

The switching arm 45 of the tracking switching mechanism MS ₂ is also set to the eighth contact, which is labeled 121 in FIG. During the duration of the series of impulses, winding III of relay HR is short-circuited by contact 47 ^ _3. After the relay F ₃ drops out, the relay HR is energized: earth, battery, switching arm 45, contact 121, relay HR ₁ winding III, earth. The relay HR responds and interrupts the circuit via the winding I of the relay U ₂ by opening the contact 73 / w. The relay U ₂ drops out and closes the contact 74? I ₂ , whereby the circuit for the magnet D ₃ is closed as follows: earth, no battery, magnet D _3j contacts 46 ^ ₃ , 113 kms ₂ , 74U ₂ , relay HR , Winding II, earth. The magnet D ₃ closes its contact 1 i ^ d _z and thereby energizes the relay U ₂ via its winding II in series with the winding III of the relay HR. The relay U ₂ responds and opens the contact 74M ₂ , thereby interrupting the circuit for the magnet D ₃ , which opens the contact Ιΐ4 <4. The relay U ₂ now drops out and closes the contact 74M ₂ . This game is repeated until the switching arm 45 reaches the contact 122. This

Contact cannot be reached through the first series of current impulses that can be transmitted by the calling subscriber (no more than io current impulses). As soon as the switching arm 45 reaches contact 122, the following circuit is established: earth, battery, resistor 46, switching arm 45, contact 122, winding I of relay V ₃ , wire 60, contact 123, switching arm 62, contact 58C ₂ , earth. The relay V ₃ is responsive to interrupts the circuit for the automatic indexing of the Mitlaufschaltwerkes MS ₂ by opening the contact 4Oy ₃ and turns the rotary magnet D ₃ through the contact 48 ^ ₃ to the surge contact 5ia ₂ at. The tracking switching mechanism MS ₂ has now been brought into a position from which it can be switched on by the second series of impulses. When the second series of impulses is emitted, the relay A _{2 is} actuated again in the manner already described, which activates the rotary magnet D ₃ via its contact 51 Ct ₂ . In the circuit of the rotary magnet D ₃ is the winding II of the relay V ₃ , so that this relay remains energized for the duration of the series of impulses. The excitation of the relay V ₃ after the switching mechanism 45 was set to the contact 122 also caused the relay HR to drop out, which prevents the rotary magnet D _{4 of} the pickup switch ZS ₂ from being excited by the relay A _2.

It is assumed that the second series of impulses consists of only a single impulse and accordingly the switching arm 62 of the following switching mechanism MS _{2 is set} to the contact 124 via which the switching arm 125 of the zone switch ZS ₁ is switched on. After preparation of the compound and opinion, extension of the requested subscriber is again excites the re j iais B ₂ in the manner already described, which herbej.- the adjustment of the exhaust j clutch switch ZS ₂ by one step leads. The holding arm jj of ZS ₂ is therefore on contact 92. In addition, however, in this position of ZS _2, contacts 126 1 and 12 ¹ JSS _{2 are} closed. The relay S ₁ is again, as already described, _{energized via the contact 104Jb 2} and has switched on the relay U ₂ via its winding II, so that the contact I28i « _{2 is} opened and the | Contact 129M _{2 is} closed. ^!

The counter incremental device is assigned a time switch Ze , which is activated by the magnet D ₅ in certain time segments ^! will provide. After the contact J 129M ₂ is closed, the timer switches out of its idle mode! brought in position by the magnet D ₅ is excited as follows j; Earth, breaker 130, contacts 131 b ₂ , 1262S ₂ , normally closed contact 1322g, contact 129M ₂ , rotary magnet D ₅ (se), battery, i earth. In the first step of the timer '' ZE , contact 1322g is opened and contact 1332g is closed.

In the present exemplary embodiment it is assumed that the time switch 36 has contact controls and is switched on by a time contact 134.uk that closes every 5 seconds. The time contact is ^one example of an electric methods gege- PM. ben. One cycle of the timer therefore corresponds to a duration of .3 minutes, which has been assumed to be the time unit for the connections. Shortly before the end of one cycle of the timer, the I contact 134 is closed. As a result, the I speaking participants are given a ^{buzzer signal 1} , from which they can recognize; that a conversation time of 3 minutes expires in a few seconds and if the conversation is continued an additional fee will be charged. The when the contact ge-1 connected, the buzzer signal transmitting I circuit is as follows: earth, sec- ¹ dary winding of the induction coil 135, contact 13Oi _2, switching arm 137, contact ^1342g: winding II of the relay B _2, winding II of the relay A ₂ , earth, The buzzer signal is transmitted from the windings II of the relay A ₂ and B ₂ to the windings I of these relays and can therefore be heard by the participants. If the timer reaches the last contact (the 36th) during its rotation, the drive magnet D _{6 of} the zone switch ZS ₁ is excited as follows: Earth, 135, contact 136 £ 3,! Switching arm 13-7, contact 1382g, magnet D ₀ (SS ₁ ), battery, earth. The zone switch ZS ₁ is adjusted by one step. The switching processes described above are repeated _: with every rotation of the ZE time switch.

The contacts of the gej by the timer-controlled zone Ze ZS switch ₁ are connected to the contacts of the Abzählschalters ZS. ₂ The switching arm 125 of ZS ₁ is switched on for connections in the second traffic zone. The normally closed contact 139 is connected to the fourth contact 140 of the tap switch ZS ₂ . Since the tapping switch, as has already been explained, is located on the first contact 92, it has to carry out three steps before the switching arm JJ reaches the contact 140. For each call unit, three counting current impulses are to be transmitted for connections in traffic zone II. If the zone switch ZS _{1 has} been adjusted by one step after the first time unit has elapsed, the switching arm 125 is located on the contact 141, which is connected to the seventh contact 142 of ZS ₂ . In the case of connections to the traffic zone III, as has been assumed in FIG. 2, the switching arm 143 is switched on. The normally closed contact 144 on which this switching arm

stands, "is connected to the 'sixth contact 145 of ZS _2. In the case of connections in the III.
S In the case of connections to the IV. Traffic zone in which the switching arm 146 VOnZS ₁ is switched on, seven counting current surges are to be transmitted for each call unit and nine counting current surges are to be transmitted for a connection to the V traffic zone.

In the present arrangement, facilities are also provided through which the duration of the individual conversations is limited according to their value. This is achieved with the ZS ₂ tap. In the exemplary embodiment assumed, the tapping switch has 32 positions. The last five contacts 147 to 148 are multiply connected to one another and connected to a relay T ₃ .

Since the zone switch ZS _{1 is} always adjusted by one step after 3 minutes, the switching arm 125 of the zone switch ZS ₁ reaches the ninth contact 149, which is connected to the contact 147 of the tapping switch ZS, after eight time units _{2 is} connected. If a conversation lasted such a long time, i.e. 24 minutes (= 8X3), the relay T _{3 is} excited in the following way: earth, contact 58c, switch arm 62, contact 124, switch arm 125, contact 149, wire 150 , Contact 147, relay T ₃ , battery, earth. The relay T ₃ responds, ött'net its contact 136 and connects the buzzer signal via its contact 151 to the windings II of the relays A ₂ and B ₂ . The calling subscriber receives the buzzer immediately. In addition, however, contacts 69 and 79i _{3 are also} interrupted and contact I52i _{3 is} closed. The speech connection is interrupted as a result. Nevertheless, the relay B _{2 is} kept energized via the contact 152J ₃ and the resistor 68. For example, if a connection to the traffic zone V has been established, the switching arm 62 of the follow-up switching mechanism MSn is on the contact 153. It becomes the switching arm 154 switched on by ZS ₁ , the break contact 155 of which is connected to the tenth contact 156 of the tapping switch ZS ₂ . With such a high-quality connection, twice the time unit has been assumed to be the longest call duration. After the first time unit has elapsed, the switching arm 154 of the switch ZS _{1 is switched} to the contact 157, which is connected to the contact 158 of ZS ₂ . After this second time unit has elapsed, the drive magnet D ₆ from ZS ₁ again receives a new current impulse and the switching arm 154 reaches the contact 159, which is connected to the contact 160 of ZS ₂ . The relay T ₃ is then immediately excited , which brings about the switching processes already described.

If after the end of a call in one of the traffic zones II to V the calling. Subscriber hangs up his receiver, there is again, as already described, the excitation of the relay A ₂ , which sends a counting current surge via the wire 41 to the counting transmission

■ relay ZR in Fig. 1 sends out. Here, the relay HR is again excited, which switches the drive magnet β _i of ZS ₂ to the impulse contact 5Ia ₂ by closing the contact 105. Relay HR short-circuits relay A ₂ at contact 106Ar, so that A ₂ drops out with a delay and contact 5Ia ₂ in the circuit of magnet D ₄ and contact iooa ₂ in the circuit of relays HR and ZR opens. The magnet D ₄ drops out, and after a while also the delay relay HR. The relay A ₂ now responds again and causes a second pulse current to be sent and the tapping switch ZS _{2 to be switched} . This game is repeated until the switching arm 77 comes to a contact via which the relay B _{2 is} short-circuited. If the zone switch ZS ₁ was advanced three times during the conversation in the second go traffic zone, the switching arm 125 stands up

, the contact 161, which is connected to the contactless of the tap switch ZS ₂ . If the switching arm 77 reaches this contact, the relay B _{2 is} short-circuited, since earth is connected to the switches 77 via the contact 5Sc ₂ , switching arm 62, contact 124, switching arm 125, contacts 161 and 162. The relay B " drops out, opens the contacts 93 and IO4 & 2, whereby the relays C ₂ and S _{1 are} permanently de-energized.

_{Contact 127, W 2} , which is only closed in the first position of tapping switch ZS ₂ , that is, when switching arm 77 is on contact 92, was opened immediately at the start of the counting current transmission. · Switching the timer Ze during the; This renders counting current impulse transmission impossible.

If the relay U ₂ loses its excitation after the relays B ₂ and S ₁ drop out, the switching mechanisms MS ₂ , ZS ₁ , ZS ₂ and Ze are switched to the rest position. The switching takes place through the interaction of the drive magnets with the relay U ₂ . The circuit for the drive magnet D _{6 of} the timer Ze is closed via: earth, battery, magnet D ₅ , contact 128M ₂ , head contact 170JiZe ₁ relay HR, winding II, earth. The magnet D ₅ closes its contact

■ 1.71 d _s and thereby energizes the relay U ₂ ,

which opens the contact 12Sw ₂ , so that D ₅ loses its excitation. Relay U ₂ is now de-energized and closes its contact 1 2Su _{2 again} , so that the magnet D ₈ receives a new current surge. If the time switch Ze seme reaches its rest position, the ijokse contact is open. The scrom circuit for the drive _{magnet P 6 of} the zone switch ZS _x is closed: earth, battery, magnet D _a , contact ijzkze, IXJu ₂ , relay HR, winding II, earth. The magnet D ₆ excites the relay U ₂ via its contact 173. If the zone switch ZS _{1 reaches} the rest position, the contact _{172IeSS 1 is located} , and further excitation of the magnet D ₆ can no longer take place. The circuits for the magnets D ₃ and D _it which bring the tracking switching mechanism MS ₂ around the zone switch ZS ₂ to the rest position have already been described earlier. Occupancy of the connecting line VL ₁ is prevented as long as any switching mechanism MS ₂ , ZS ₁ or ZS _{2 is} still in the working position. This is achieved by the relay HR, which via its contact 146 closes a circuit for the relay S on the transformer U (Fig. 1). As already explained, the relay S is excited during the triggering movement of the tracking switching mechanism MS ₁ via the head contact 10 ″ JkMs _1. If the tracking switching mechanism MS _{1 is} in the rest position, the contact 10JkWiS _{1 is} opened and the contact ι j ^ UmS ₁ If the relay HR in Fig. 3 is still energized at this time, the relay S is kept energized as follows: earth, resistor 176, contacts 140 / ir, 42C ₂ , wire 41, contact ij $ kms _x , so that an occupancy of the connecting line VL ₁ by a tested second selection II. VW is impossible relay S, battery, earth. therefore, the relay 5 maintains its contact open iS s _1.

In the case of a connection between the subscriber Tw _{3 of} the main exchange HA (Fig. 4) with a subscriber of an exchange, which via the connecting line VL ₁ . is reached, after setting the preselection elements I. VW ₂ (Fig. 4) and II. VW _2, the relays C ₀ , A _e and B _{6 are} energized. The first number surge receiver / is set in a manner known per se. Is GfF ₂ to a row of contacts, in which the connecting line VL _i% reasonable, closed. Upon finding such a \ idle trunk following 'occurs: Circuit concluded: earth, coils I and II of the relay P _3, contact 2o6r _6, shifting

207, contacts 205 and 2o8z / _s , relay C-, wire 209 of the connecting line VL ₃ , branch point 202, wire 210 of the connecting line FL ₆ , to the battery via switching 60 orginal selector in the remote exchange. The relay C ₁ closes the contact 2iic ₇ lying parallel to the contact 2o8 &> ₈ and energizes the relay V ₈ via the contact 2i2c ₇ , the contact 213 of the tracking switch mechanism MS ₃ and the switching arm 214 , which opens the contact 2o8ü _{8 and} the relay A ₇ connects via the contact 21 ζν _& to the battery via the resistor 216. Between the connecting lines FLg and VL ₉ are the switching elements of the counter indexing devices, consisting of the switching mechanisms MS ₃ , ZS ₁ and ZS ₂ . The mode of operation of this counter incremental device corresponds to that shown in Fig. 2, so that a description of the switching processes is superfluous. The relay B ₇ corresponds to the relay B ₃ and the relay T _{1 to} the relay T ₃ .

Claims (3)

80 patent claims: 1. Circuit arrangement for telephone systems with dialer operation and automatic separation of the connection after a certain time, characterized in that switching devices (ZS ₁ , ZS ₂ , relay T ₃ ) on the connecting devices or lines (VL ₁ ) according to a by the valence of the produced Connection for a certain period of time (e.g. 12 minutes) cause the connection to be automatically disconnected. 2. Circuit arrangement according to claim i, characterized in that the disconnection of the connection is caused by the switching devices (ZS _x , ZS ₂ ) causing the incrementation of a counter (Z) according to the values of a connection (by means of the relay T ₃ ). 3. A circuit arrangement according to claim 2 for systems with counting of the compounds at the end of the call, characterized in that a the Zurwirkungkommen the counter pawl (ZS ₂₎ preparatory switching element ^ relay B ₂₎ inducing by ds, the separation of the connection switching element (relay T ₃₎ in which the transmission of the meter current impulses is held (contact closed). In addition 4 sheets of drawings.