DE665908C - Circuit arrangement for telephone systems with two-wire connecting lines - Google Patents

Description

Circuit arrangement for telephone systems with two-wire connecting lines The present invention relates to a circuit arrangement for telephone systems with two-wire connection traffic. This can cause malfunctions in such systems occur that the connection devices at the incoming end of the connection line erroneously assigned, but no longer triggered. The erroneous assignment can occur through fault current surges, which z. B. by earth fault of a wire or mutual Touch both wires on the cable. A trip that way occupied connection devices no longer takes place because of the fault current surges usually further current surges, which are the current surges required for triggering would correspond, not follow.

The present invention avoids the disadvantage set out above by an occupancy relay at a certain potential on the incoming one End of the connection line, which is caused by an occupancy current surge in a certain direction, generated by applying higher potential of the same polarity at the outgoing line end, stimulated, but kept excited in a local circuit only when the stimulus current results in a magnetic flux in the same direction in the relay as the holding current. Another form of solution, do to eliminate the mentioned disadvantage, is that the occupancy relay at the incoming line end has a winding of high resistance due to a current surge of sufficiently high voltage or a rectifier, Capacitor or discharge path due to a high voltage and certain current surge Direction stimulated and kept excited in a local circuit, which the latter interrupted again by the triggering shock acting on the occupancy relay will.

The accompanying figures show various exemplary embodiments of the invention. Fig. Ra shows a two-wire connecting line lL with the two wires a and b. At the incoming end of the connecting line, the occupancy relay B of the connecting device arranged here, e.g. B. a transmitter or a group selector. The relay B has three windings, of which the winding I lies directly on the a, -wire, the winding III is connected to the b -wire via a glow lamp GL, while the winding 1I is excited via the contact b, in a local circuit can be. During the assignment, the contacts _r of a relay X (not shown) are temporarily closed at the outgoing end of the connecting line. As a result, a current surge is generated in the primary winding I of the transformer Tr, which induces a positive induction surge when the current in the winding I of the transformer Tr rises and a negative induction surge in the secondary: winding II of the transformer when the current decreases: 'The positive part of the induction shock is suppressed in a way that is not of further interest here. The negative part of the induction surge has such a potential that a current flows through the a-wire in the direction: earth, battery, winding I of relay B, contact 12, a wire of connecting line VZ, winding II of transformer Tr, earth. Relay B responds in this circuit and, via contact bi, closes a local holding circuit for winding 1I of relay B. By opening contact b.> Relay B switches itself off from the a-wire. The winding sense of the winding I of the relay B is such that the fields generated by the circuits described above in the windings I and 1I of the relay support each other. If, on the other hand, an earth pulse were to come to the a-wire, for example due to a temporary earth fault or a collision of the lines, the current flow in winding I of relay B would run in the following direction: earth, a-wire, Koiitalctb.2, winding I of the relay B, battery, earth. Relay B would also respond in this circuit, but since there is now an opposing field in winding I of relay B to the field generated in winding 1I, relay B would drop out again after this missing pulse.

Instead of a negative induction surge through the transformer Ti can be the corresponding current flow in the assignment in winding I of the relay D, as shown in dashed lines, also by generating a negative potential by means of a high voltage DC battery, e.g. B. of 120 volts, on the outgoing End of the connecting line are generated.

Also due to the discharge currents of the capacitors K, as indicated by dotted lines, a corresponding current flow in the winding I of the relay B with the assignment reach.

Another embodiment is shown in FIG. in which the corresponding current flow through. an alternating current source 117Q applied at the outgoing end during the occupancy and a rectifier GR connected upstream of the winding I of the relay B at the incoming end in a corresponding sense is achieved. Otherwise the switching operations are the same; as shown in Fig. ia.

The connection device is triggered at the incoming end via the b-core. The transformer Tr is at the outgoing end of the line applied to the b-wires by switching processes of no further interest here and "le" iin the closing of the contact y an induction surge via the connecting line sent out, which in the winding lying in the series with the glow lamp GL III of the relay B generates a field that corresponds to the field in the holding winding II of the relay B is directed in the opposite direction and thereby causes the occupancy relay B to drop.

In Fig. 2, too, the assignment via the aAder of the connecting line VZ by means of the transformer Tr or the capacitors I ((shown in dashed lines emitted a current surge from the outgoing end of the connection line, which however, a current flow is generated in the following direction: earth, winding II of the transformer Tr, a wire, winding I of relay D, battery, earth. The relay B speaks in this Circuits and is maintained after your occupancy current surge via a contact 1l and its winding II in a local holding circuit. A special sense of winding winding I of relay B is not required in this version; a response of relay B via its winding I due to incorrect pulses is prevented here that the winding I of the relay B is made so high that the relay on fault current surges do not respond, but because of the relatively high voltage of the Transformer Tr emitted induction surge can be excited: The tripping takes place again, as shown in Fig. 1a, by a sent out via the b wires Induction impulse, which is via a third in series with a glow lamp Winding of relay B causes the occupancy relay to drop out.

In Figs. 3a, 3b and: I an erroneous actuation of the occupancy relay due to missing pulses with the help of capacitors switched into the occupancy circuit or Gliminlainpen prevented.

In Fig. 3a, the occupancy relay B at the incoming end of the connecting line has only one winding: During occupancy, a positive induction surge is emitted via the transformer Tr by temporarily closing contact x at the outgoing end of the connecting line, which at the incoming end the linear line GLx ignites (or, as shown in dashed lines, results in a charging current surge via the capacitor Ko) and thereby - causes the relay B to respond in the following circuit: Earth. `` F'icklung 1I of the transformer Tr, a-wire of the connection line 1'L, glow lamp GLi, winding of the relay B, battery, earth. The relay B is kept in a local circuit by closing its contact bi. It is triggered by the fact that the transformer Tr, when the contact y is temporarily closed, emits an induction surge in a negative direction via the b -wires, which ignites the glow lamp GL @ and causes a current flow in the winding of the relay B, the direction of which is that of the local circuits Direction is opposite so that the relay comes to waste. The exposure of unsuitable induction surges during occupancy and release is prevented in some way that is not of further interest here.

In FIG. 36, the occupancy relay B has again, as in FIG. 3a only one winding; However, it is not used over both cores, namely during the assignment over one wire and, when triggered, over the other wire, but only over one The wire in the connecting cable is affected. The occupancy takes place when closing of the contact a via the transformer Tr a negative induction process, which the glow lamp GL ignites and the I'f ^ lais B is excited in the following circuit: earth, Wrapping of relay D, glow lamp GI_, b-wire of the connection line, winding l1 of transformer Tr, earth. The relay B slams; I after it has responded in the following local circuits: earth, winding, of relay B, contact bi, battery, earth. During the dissolution, the temporary closing of contact y becomes positive Induction shock emitted via the b -wires, which occurs after ignition of the glow lamp GL in the relay B results in a current flow, "-elchen the current direction of the local circuit is directed in the opposite direction and thereby causes the relay to drop out.

FIG. 1 shows an embodiment of the invention in which the occupancy relay I> ain the incoming end of the connecting line has two windings, one of which is connected to a wire of the connecting line via a glow lamp. During the occupancy, a negative induction surge is given to the a-wire by briefly closing the contact x from the outgoing end of the connection line via the winding 1I of the transformer Tr, which after ignition of the Glimnih I 'L, via the winding 1 of relay B nipe G causes the occupancy relay to respond. Instead of the Glinun lamp GLi, the induction surge can also run via the capacitor Ko. After the current surge has ended, (read relay B in the following local circuits: earth, winding I of relay B, contact bi, battery, earth Positive direction induction shock emitted via the b-wire; this ignites the glow lamp GL., at the incoming end of the connecting line. The winding sense of winding II of relay B is such that after ignition of glow lamp GL., in winding II of the relay B generated zl £ trigger sistromschlag an opposing field to the locally energized winding I is generated and thereby the release of the relay B is brought about.

Claims (12)

PATENT CLAIM: i. Circuit arrangement for telephone systems with two-wire connecting cables, characterized by one at a certain potential lying occupancy relay (B) at the incoming end of the connection line, which due to an occupancy surge in a certain direction, generated by creating higher ones Potential of the same polarity at the outgoing line end, stimulated, but only then is kept energized in a local circuit when the stimulus current is an illagnetic flux the same direction in your relay as the holding current. 2. Circuit arrangement for telephone systems with two-wire connecting lines, characterized in that the occupancy relay at the incoming line end is stimulated via a winding of high resistance by a current surge of sufficiently high voltage or via a rectifier, capacitor or discharge path by a current surge hofier Spannull-, and in a certain direction local circuit is kept energized, which latter is interrupted again by the release surge acting on the occupancy relay (Figs. 2, 3a, 31) and d). 3. Circuit arrangement according to claim i, thereby marked that the occupancy relay (B) with proper occupancy via a ini occupancy circuit lying winding (I) is excited and is via another Winding (1I) binds in a local holding circuit. .. Circuit arrangement according to @ nspruch 3, characterized in that the winding in the occupancy circuit of the Occupancy relay (I13) is switched in such a way that the properly Occupancy produced current flow in this winding that in the local holding winding (II B) generated field supported, while the generated by fault current surges Current flow in the winding (IB) in the occupancy circuit has an opposing field to that in the local excited holding coil (IIB) generated field which causes the waste of the occupancy relay (Fig. ia). 5 .Circuit arrangement according to claim i and z, characterized in that the occupancy relay (B) when triggered by an induction surge running over a wire of the connecting line, which at the incoming end of the line a winding (III B ) of the occupancy relay is affected, is brought to waste. 6: Circuit arrangement according to Claim 5, characterized in that the trigger current surge in the winding (11I B) influenced by it, an opposing field compared to the holding winding (IIB) of the occupancy relay and thereby causes its drop. 7. Circuit arrangement according to claim i and z, characterized in that the winding in the occupancy circuit des, occupancy relay (I B) at the incoming end of the line by an induction surge, by a direct current battery or the discharge current of capacitors to effect is brought. B. Circuit arrangement according to Claim 2, characterized in that the winding of the occupancy relay (I B) in the occupancy circuit by alternating current (WQ) via a switched on in the occupancy circuit with the corresponding sense of direction Rectifier (GR) is brought into effect (Fig. Il ». G. Circuit arrangement according to Claim a, characterized in that the occupancy relay through the occupancy a current surge is stimulated by a connected Glimm lamp or a capacitor and when triggered by a glow lamp is influenced by a current surge, which has the same or different direction as the occupancy current surge '(Fig. 3a, 31), 4). ok Circuit arrangement according to Claim 9, characterized in that the occupancy relay is only provided with a single winding via which the Relay due to the induction surge when occupying one wire and one upstream Glow lamp (GLl) stimulated after occupancy incentive in a local holding circle kept excited and when triggered via the other wire and one between them and the relay winding lying further glow lamp (GLn) is brought to waste (Fig. 3a,). i i. Circuit arrangement according to Claim 9, characterized in that the occupancy relay (B) in series with a glow lamp (GL) when occupied and tripping via the same wire of the connection line due to different current surges Direction is influenced (Fig. S U). 12. Circuit arrangement according to claim 9, characterized characterized in that the occupancy relay (B) in the occupancy on the one winding (I B), a glow lamp or a capacitor and one wire of the connection line energized and after switching off this winding from the occupancy circuit in one local circuit is kept energized, when triggered, however, via a second Winding (II B), another glow lamp and the other wire is affected (Fig.4).