DE2424705C3 - Circuit arrangement for switching off the ringing tone in telecommunications, in particular telephone switching systems - Google Patents

Description

The invention relates to a circuit arrangement for switching off ringing currents in telecommunications, in particular Telephone switching systems, with one connected to the subscriber lines, a direct and a ringing circuit containing an alternating voltage source and provided with a transmitter circuit a detection circuit that is galvanically separated from the ringing circuit, through which one in this ringing circuit flowing direct current is distinguishable from an alternating current, as well as with one when responding Detection circuit the ringing circuit from the subscriber lines isolating relay control.

A known circuit arrangement of this type (DE-OS 22 55 752) contains a ringing circuit which is provided with a transmitter circuit which essentially consists of a resistor and a light-emitting diode. In series between the resistor and this diode is a low-pass filter which keeps the alternating ringing current flowing through the ringing circuit away from the diode. Only when the called subscriber closes the subscriber loop by picking up his handset and thus a direct current can flow through the ringing circuit _t the diode is excited to glow and sends a signal to a phototransistor. The phototransistor is part of a detection and control circuit that evaluates and amplifies the output signal of the transmitter circuit, which interrupts the ringing circuit via suitable relays, after which ringing current can no longer reach the subscriber devices.

For some applications, the sensitivity of the known arrangement is not sufficient, since both some of the DC current through the resistor as well

ίο part of the alternating current through the low-pass filter and the light emitting diode flows. The difficulties that arise can only be resolved with a avoid large circuit costs.

In another known circuit arrangement for ringing current shutdown (DE-OS 23 07 317) is an im essentially consisting of a resistor and an oscillator transmitter circuit through a resonant circuit transformer, which forms part of the oscillator, galvanically from a detection and control circuit separated There is a low-pass filter between the resistor and the oscillator, that certain AC components can reach the detection circuit via the oscillator and the transformer. Here, too, the sensitivity required for some applications can only be achieved with a high level of sensitivity Reach circuit upw.

Another known circuit arrangement for ringing current shutdown (DE-OS 19 56 200) contains a Series connection of a Rufabschaltelais, a diode and a capacitor as well as a DC voltage source or office bat erie, a subscriber line and a called subscriber station. The condenser bridges those from the ringing current source, the subscriber line and the called subscriber station on the one hand and the series connections formed from the diode, the Rufabschaltelais and the office battery on the other hand. It is constantly charged by the official battery, through a parallel resistor that the Series connection of the diode and the Rufabschaltelais bridged, so that during the call duration, if only AC or ringing current flows through the called subscriber station, the relay is not energized. Only when the called subscriber picks up his handset and thus closes the C i 'oichstromleitungsschleife, can Direct current from the office battery to flow into the series circuit from the called subscriber station and the call disconnection relay exists. The call canceling relay is operated by a direct current detection circuit switched between its two states.

The parallel resistance mentioned must be smaller than the winding resistance of the Rufabschaltelais. Otherwise a large part of the capacitor charge would flow off via the Rufabschaltelais, causing this would be excited during the calling period. When the called subscriber closes the DC loop, by picking up his handset, the increased direct current must control the Rufabschaltelais in said Excite row circle. It should therefore be very sensitive, especially as most of the current is Parallel resistance flows through On the other hand, a very sensitive relay is also disadvantageous, since it is during the Calling period is flowed through by part of the capacitor current. Therefore it should be as insensitive as possible be. An insensitive Rufabschaltelais is also disadvantageous because it may not responds when a called subscriber who is connected to the exchange via a long line his Handset picks up, the well-known circuit arrangement

tion is therefore problematic if it is to be suitable for both long and short trunk lines.

Finally, a circuit arrangement for ringing current transmission is known (DE-AS 10 21 899) in which a voltage source that emits the ringing current is located in one of the subscriber's speech wires and one has internal impedance that is not negligible at the time of the call transmission, on the other hand when the Participant has picked up the phone is very small. This impedance is formed by the secondary winding of a transformer that is in the line between a supply transformer and a call station. If the called subscriber picks up the receiver, see above the hook switch switches through the line to the intercom, which is then fed by direct current from a shared battery is fed. This microphone feed current flows through the secondary winding and saturates the transformer's magnetic circuit. The apparent inductance or reactance of the transformer becomes very small and represents only a low resistance for speech currents. The impedance of the The transformer winding is therefore variable and it serves the purpose of, on the one hand, the ringing current in the To feed in the alarm clock circuit, on the other hand, to oppose the speech currents with as little resistance as possible. However, it does not serve to differentiate between direct currents and alternating currents and in dependence from the flowing or non-flowing of a direct current, the ringing alternating current from the subscriber lines or to connect to them.

The invention is based on the object of providing a circuit arrangement of the type mentioned at the beginning create that is very sensitive despite its simple structure

According to the invention this object is achieved in that the transmitter circuit has an inductance with a having an interrupted core by an air gap, and that in this air gap with a flat component a resistance that depends on the strength of the magnetic field is inserted

Advantageous further developments of the invention are characterized in claims 2 to 5.

It is advantageous in the circuit arrangement according to the invention in particular that they are very insensitive to voltage fluctuations in the ringing circuit is. The magnetic resistance of the part of the core having the air gap is namely much greater than that of the rest of the core, so that it absorbs almost all of the magnetic flux the air gap is very small and the flow changes caused in it by the Rufstrorn have a negligible influence on the resistance of the flat component protruding into the air gap.

Embodiments of the invention are explained below with reference to the drawing. It shows

F i g. 1 shows a circuit arrangement according to the invention,

FIG. 2 shows one in the circuit arrangement according to FIG delay circuit used,

F i g. 3 and 4 two further embodiments of an eo circuit arrangement according to the invention.

In Fig; 1 shows, as part of an automatic telecommunication network, an arrangement for differentiating between direct and alternating currents, consisting of a ringing current disconnection arrangement RA _t, a control circuit CC, a calling and a called subscriber station 751 and TS 2.

The calling and called subscriber stations TSi and TS2 are connected in a known manner via the subscriber lines a '\, b' \ and a'2, b'2 and the contacts 11, 612 of a relay (not shown). Each of these stations contains a subscriber set with a handset, ringing circuit and hook switch. For example, station TS2 contains a ringing circuit, which is shown schematically as a coil / and which forms a series circuit with a capacitor C , which is connected in parallel to the hook changeover switch h

If connection paths to the calling subscriber TSX and the called subscriber TS2 are established, the ringing tone is sent to the calling subscriber station TSi and the Rufstromverschalteanordnung RA to the called subscriber TS 2 via the closed contacts al, a Z. Contacts oll, 612 are still open. If the called subscriber picks up his handset, the ringing current is interrupted and the contacts 611, 612 are closed; the connection between the calling and called subscriber is established

The aforementioned ringing current switch-off arrangement consists of a direct and alternating voltage source B and RC ·· id of a discriminator circuit for differentiating between direct and alternating currents with an input and an output circuit. The input circuit consists of a variable impedance and the output circuit includes a sensing circuit, an amplifying circuit and a call disconnection relay RTr.

The positive pole of the DC voltage source B and the one connection point of a secondary winding tv2 of a transformer T2 are grounded while the negative pole of this Gleirh voltage source B is connected to another secondary winding w 1 of the transformer T2 whose primary winding is fed from the AC source RC via the normally open contact ir. This contact can be switched intermittently in order to generate an interrupted ringing current for the called subscriber. It should be noted that the means for the intermittent switch are only indicated schematically because they are not essential to the invention.

The other connections of the secondary winding w 1 and w2 are connected to the wires a'l and a'2 as well as b '\, b'2 of the subscriber line via resistor R 1, working contact a 1 and the resistors R 2 and RS and working contact a 2 . The normally open contacts a I, a 2 belong to relay Ar. The variable impedance is composed of resistance R, inductor L diode DS and a light emitting diode LED that is part of an electro-optical unit ode "· opto-isolator OI, z. B. Type MCT? By Monsanto. This opto-isolator OI further contains a light-sensitive element, the phototransistor TO, which is separated from the borrowed (emitting diode. The light-emitting diode generates a light flux with a positive bias voltage. The light flux generates a base current in the phototransistor, which increases with the light intensity. As with any other transistor Here, too, the collector current rises with the base current. The resistor /? S are connected in parallel with the oppositely polarized diodes DS and LED in series with the choke coil L. The diode LED is polarized in such a way ₍ that it is positively biased by the direct voltage from the source B.

It should be noted that instead of the opto-isolator too a piezoelectric coupling element can be used,

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The detecting circuit contains the phototransistor TO and a delay circuit DL with the associated input and output terminals Ml, M2 and / V / 3, M4. The grounded collector and the emitter of the transistor TO are connected to the input terminals M 1, M 21 of the associated delay circuit DL , which is shown in P i g. 2 is shown in more detail.

The amplifying circuit contains the pnp transistors rail and TR 12 and the resistors / 32, / 33 and 34 in a known Darlington circuit. The output terminals M3 and M4 of the delay circuit DL are connected to the base of the transistor TOH and via the associated contact s I to the negative pole of the office battery. The official positive battery post is grounded. The connection point of the collectors of transistor TO 11 and TO 12 is via the excitation winding of the ringing current switch relay RTr in

C _n ..; ** _m : »J _nm λ Λ _Α ;«. Ι »..ι. * ..:« j— η - «« ..:. UVl H, mil UbIIl ΓΛί L / liIiaiWIKCIIM J IIIIl UCI LfCtICfIC

tied together. The excitation winding is bridged with the diode DRT in order to divert the stored energy. when the transistors TOIl and TO 12 are blocked.

The control circuit CC contains the relays Ar, .5rund Gr with the associated contacts a 1, a 2, a 3. s. S 1 and g. The latter two relays are not essential to the invention; they are mentioned to understand how they work. One connection of the excitation winding Ar isl is connected to the output of the pulse supply source P via relay contact g on the one hand and on the other hand via relay contact a 3 and resistor R 5 to the battery. The other connection of the excitation winding is earthed via contact rtr.

FIG. 2 shows a delay circuit DL as used in FIG. The cathode of the Zener diode Z5 is connected to the input terminal Mi and the anode to the connection point to which the resistors R 25, R 28, R 26 and the capacitor C11 are connected. The other connection point of the resistor R 25 is the output terminal M 4, whereby the anode of the Zener diode Z5 is held at a constant negative potential Z'5 when contact 51 is closed. The other connection of the resistor /? 28 is connected to the common cathode connection point of the diodes DlO, DIl and the connection point of the other connection of resistor 26 and capacitor CIl to the anode of D10, which is connected to the input terminal M 2 via the resistor R 27 .

Regarding F i g. 1 and 2 it is assumed that the relays Sr and Gr are energized by the control circuit CC , so that the contacts s, s 1 and g are closed and, moreover, the diode LED does not emit any light. As a result, phototransistor TO does not conduct

The transistors T011 and TO 12 are conductive, since the negative Zener voltage Z'5 28 and the diode Dll is applied to the base of transistor TO 11 via the current limiting resistor R. The Rufabschlalterelais ÄTrwird energized and closes the contact rtr which the excitation winding of / ir connects to earth Since the contact g is also closed, the relay Ar is energized when a negative voltage pulse from the pulse supply source P is applied to the other end of the excitation winding.This pulse appears when the called subscriber TS2 has been connected.Thus, the contacts al, a2 and a3 as closed. The latter holds the relay Ar via resistor R 5. The ringing current can now flow in the ringing circuit /, C of the called subscriber station TS 2. This closed circuit contains the secondary windings w Ij w2 of the transformer 7 * 2, the DC voltage source B, the resistors R 1, Λ2, the closed contacts a X ₁ a 2, the resistor RSm \\. its parallel circuit, the wires ä'2 and b'2 lind the series circuit / C of the participant station TS2. The contacts b Ü and b 12 are still open, so that no ringing current can flow to the calling Teilriehrnerstätiön TSl *

As long as the called subscriber TS2 has not picked up his handset, contact Λ remains open so that no direct current can flow through the loop. The part of the ringing current that is diverted via the series connection of the choke coil L and the diodes DS and LED connected in parallel is very small because of the impedance of L, which is very high compared to the resistor RS. The small rectified half oscillations, the LED

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UUiLIiMiCLfCIf ₁ vciuisauicfi cmc * ci ifainrasaigisai (wcitic light emission that does not change the output impedance of the opto-isolator Ol . This means that the transistors TR 11 and 77-12 remain conductive and that the relay RTr is picked up and the contact rtr remains closed. The Diode DS limits the bias on LEDs in the reverse direction of flow.

If the called subscriber TS2 picks up his handset and thus closes contact h , the equilibrium current from source B can flow in the line loop that contains the resistance /? S with the parallel-connected series circuit of diode LED and choke coil L with its ohmic resistance. Since the ohmic resistance of the inductor L is much smaller than the resistance RS . Most of the current flows through the light-emitting diode LED, which then shines brightly enough to saturate the transistor TO. The point M 2 is thus practically brought to earth potential. The potential at the point / capacitor CIl. which until now has been prevented from charging by diode D10, is now. starting from the potential Z'5 brought almost to earth potential, since resistance R 27 is small compared to R 26, that is, the charging time for capacitor CIl is approximately R 27 CIl. When the potential at point / above the potential at the connection point of the diodes D 10 and D11 increases, the former becomes conductive, so that this connection point comes to about minus one volt, the voltage drop across the series-connected diode DIl with the base-emitter paths the transistors TOIl, TO 12 and the resistor Λ 33. The voltage drop across diode D11 is less than one volt with the small base current flowing through it, jnd resistor R 33 is chosen so that the voltage drop across the base-emitter paths is greater than the sum of the starting voltages of the transistors TOIl and TO 12, which are then blocked so that the relay RTr drops out. The base-emitter starting voltage of a pnp transistor is the negative base-emitter voltage below which the transistor becomes conductive. The dropped call switch-off relay R Tr has opened contact rtr and thus released relay Ar . The latter opens its contacts a 1, a 2, a 3, so that the ringing current is interrupted. The contacts 611, 612 are now closed by means not shown, so that the calling station is connected to the called subscriber station TS 1 and TS 2

The relays RTr and Ar have dropped out with a delay after the start of the loop direct current. The delay time depends on the time constant R27 ■ CIl, as already said without a time delay

Relay / ir would drop out again immediately after its contacts a1, a 2, a3 were closed and the ringing current would begin to flow into the capacitively loaded subscriber loop due to the high inrush current from battery B. This inrush current can saturate the phototrarisistnr TO and thus sense the Trärisislorcn TR 11, TR 12 and open the normally open contacts rtr. Relay Ar would drop out. And if, at this moment, the negative voltage pulse from Impüisqueiie P], which lasts only valued milliseconds, disappears, relay Ar would remain in its non-excited state. The ringing stream could then never reach the called subscriber.

It should be noted that the AC sensitivity of the Rufslromschalteanordnung is very low. since only a negligibly small part of the ringing current flows through the light-emitting diode LED, which has no effect on the arrangement.

It should also be noted that the inductor L can be replaced by a /? C low-pass filter, which protects the diode LED from ringing current.

In Fig. 3 and 4, the Rufstromverschalteanordnung RA and the control circuit are only partially shown. The dike and alternating current sources as well as calling and called subscriber stations are connected as in the first embodiment and the relays Grund Sr ( not shown) switch the contacts s and g. In the embodiment according to FIG. 3, no resistor RS is used; as in the first embodiment, the arrangement for direct and alternating current jo discriminating includes a variable impedance, a recognizing circuit, an amplifying circuit and a Rufstromabschalterelais.

The variable impedance in Fig. 3 is a transformer 7 "4 with a primary winding NT, which forms a series circuit with the loop, a short-circuited secondary winding NS, an air gap the width / and a section S in one of the legs. A magnetically sensitive resistor MFDR im Air gap is part of the cognitive circle, which is separated on dipsp Wpicp oali / anicr «h vnn Aar Pfjfnsr- and secondary winding.

It should be noted that, deviating from the representation according to FIG. 3, the primary winding N7 can be divided into two stair windings with equal turns, which are switched $ 0, that each loop wire flows through a stair winding and that the magnetic fluxes support each other. A split winding renders unwanted interference, which flows through both wires in the same direction, harmless in that these interference currents cause magnetic fluxes in antiphase in the core of the transformer TA , which cancel each other out.

The above-mentioned magnetically sensitive resistor MFDR has its range of action in section S of the leg; it is provided with two connections JtI and k 2, of which the latter is grounded. Such magnetically sensitive resistors are z. B. available from Siemens under the designation "field plates". Terminal k 1 is connected to the base of the pnp transistor TR 13. The emitter of the transistor TR 13 is connected to ground, the collector is connected to the pnp transistor TR 14 at the base. The base of transistor 77? 13 is connected to resistor R 30 and the base of transistor TR 14 is connected to resistor R31 . The common connection point of the resistors Ä30, Ä31 is connected to one connection of the excitation winding of the Rufabschaltelais RTr and via contacts s of relay 57- with the battery; The other connection of the excitation winding is to the collector of the transistor 77? 14 ally whose emitter is grounded. The excitation winding of the relay Ar lsi is earthed via contact rtr of the Rufabschaltelais and on the other hand connected via contact a 3 and resistor R 5 to the battery and via contact g of relay Cr to the pulse source P. The excitation winding RTr is a diode DÄrparajieigeschaitet.

The relays Ar, Sr and Cr are part of the control circuit CC, while relays RTr, transformer TA and the amplifying circuit with the transistors TR 13, TR 14 are part of the ringing current switch-off arrangement RA . When the relays Sr and Gr are energized by the control circuit CC , the contacts 5, g are closed and transistor TR 14 conducts current through the Rufabschaltelais RTr. Due to the closed contact rtr of the energized relay KIr , the relay Ar is energized when the pulse source P applies a negative pulse. As a result, the contacts a 1, a 2, a 3 are closed so that the ringing current to the called subscriber station TS 2 can flow via the primary winding Λ / 7 of the transformer TA. Relay Ar is held via resistor Λ 5 and its own contact a 3. The magnetic flux in the middle leg of the transformer TA, which is generated by the secondary winding current, is opposite to that generated by the ringing current in the primary winding; a differential magnetic flux is formed. Only a very small part of this flux is diverted into the right leg, which is provided with an air gap the width /, because the magnetic resistance of this leg is much greater than that of the left leg, which is practically a short circuit and takes over almost the entire flow . This means that the magnetically sensitive resistor MFDR is practically not influenced by the alternating flux from the ringing current. The resistor R 30 is chosen so that it is much greater than that of the MFDR and that the negative voltage drop across the latter is greater than the negative base-emitter connection Hf ¹ C nnn-Trancictnrc 77? 11 Hpr Hpcu / ρσρη

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remains in its non-conductive state.

The current through the series circuit formed by the resistors R 30 and MFDR is mainly determined by the resistor /? 30, because it is larger, so that the change in the voltage drop across the MFDR is proportional to the change in its resistance value.

When the called subscriber picks up his handset, direct current flows through the loop of the called subscriber TS 2 and also through the primary winding of the transformer 7 "4, which increases the magnetic flux through the center leg. Part of the additional flux from the web flows through the left leg and saturates this so that the remainder of the additional flux remains for the right leg with its greater resistance. The increasing flux in the air gap of width / increases the resistance of the MFDR to a sufficient extent that the increased voltage drop drives transistor 77-13 conductive power and transferred into the saturated state as a result locks transistor TR 14. the Rufabschalterelais RTr discharges its stored energy through diode DÄTund drops. As described in connection with the previous embodiment mentioned then Ar relay drops out and the ringing current is turned off

The advantage of a transformer with a short

closed winding is that the impedance on the input side is minimal. This can be easily done from the z. B. by Millman and Taub written book "Pulse, Digital and Switching Waveforms", Verlag McGraw-Hill, New York, 1965, on pages 65-68, can be derived from the equivalent transformer circuit described on pages 65-68. The above transformer impedance is set in essentially from the ohmic resistance of the primary winding, the primary and secondary leakage inductances and the ohmic resistance of the secondary winding related to the primary side and is therefore much smaller than the smallest loop resistance. The loop resistance determines hence the magnitude of the ringing current and in a given case this current is constant and of the Transformer input impedance independent. Although the air gap of this transformer is in one of the Leg is provided. A short-circuited transformer can also be used to fill the air gap in the jetty. Experience has shown that this solution is less advantageous.

A Hall plate in the air gap could also be used instead of the magnetically sensitive resistor will.

Such a Hall plate HG with the connections k 1, ir2, Jt3, k 4 is shown in FIG. The terminals Jt3 and λ 4 are connected to a constant current source CCS and the terminals k 1, k 2 are as in Fig. 3 connected. The transformer T'4 has an air gap the width / to accommodate the Hall plate. The Hall voltage at the connections ki, k2 is proportional to the perpendicular magnetic field strength. The increased Hall voltage, caused by the increased magnetic flux in the air gap, caused by the loop direct current after lifting the handset, can then be used to switch the call disconnection relay.

Instead of a short-circuited transformer, a parallel circuit made up of a resistor and an inductance with an iron core and an air gap can be used. A magnet-sensitive resistor or Hall plate is inserted into the air gap. Such a core is shown in FIG. ⁴ , in which the winding N 1 I is bridged by a resistor RS. Similar to the embodiment of Figure 3, the winding N'7 can be divided into two separate windings, each being connected to a core of the loop and each having a parallel resistance which must be much smaller than the impedance of the split winding inductance. If the above parallel circuits are used in the loop instead of the primary winding of the transformer Γ4, a fraction of the ringing current flows through the inductances, which are connected in parallel with the small resistors

When the handset is lifted, direct current flows in the loop. Since the ohmic resistance of the inductance is smaller than the parallel resistance, the direct current will mainly flow through the inductance. In this case, the amplifying circuit must be designed so that the transistor TR 13 remains blocked when the small voltage drop occurs along the magnetically sensitive resistor or the Hall plate, which is caused by the flow in the air gap from the negligible fraction of the ringing current through the inductance will. The increased MFDR clamping voltage drop or the increased Hall voltage due to the rise in flux in the air gap caused by the loop direct current or the superposition of DC and AC currents when you lift the handset, making transistor 77? 13 conductive and as a result the ringing current is switched off. It should be noted that this circuit works without a delay element.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1.Circuit arrangement for shutting off the ringing current in telecommunications, in particular telephone exchanges, with a ringing circuit connected to the subscriber lines, containing a direct and an alternating voltage source and provided with a transmitter circuit, with a detection circuit that is galvanically separated from the ringing circuit, through which a ringing circuit in this ringing circuit flowing direct current is distinguishable from an alternating current, as well as with a relay control which separates the ringing circuit from the subscriber lines when the detection circuit responds, characterized in that the transmitter circuit has an inductance (T 4) with a core interrupted by an air gap (I) and that in this Air gap (I) a flat component (MFDR; with a resistance dependent on the magnetic field strength) is inserted. 2. Circuit arrangement according to claim 1, characterized in that the inductance is designed as a transformer (T4) whose primary winding (N 7) is in series in the call circuit (B, RC, R \, R2, a'2, b'2) and its secondary winding (NS) is short-circuited. 3. Circuit arrangement according to claim 1 or 2, characterized in that the inductance (T5) has two primary windings lying in series in each of one of the two wires (N9, NiO) de " ringing circuit (B, RC, R 36, R 37). 4. Circuit arrangement r.jch one of the preceding claims, characterized in that the transmitter circuit has at least: an ohmic resistor (TiS;) lying parallel to the inductance (T '4). 5. Circuit arrangement according to one of the preceding claims, characterized in that the flat component (MFDR) is designed as a Hall generator (HG) .