CH652549A5 - Circuit arrangement to block outputs of one or more selection stages in telephone exchange systems - Google Patents

Description

The invention relates to a circuit arrangement for blocking the outputs of one or more selection stages, which are connected to the inputs of a following switching arrangement.

In exchange switching systems, switching arrangements are often used according to dialing stages, which combine the many outputs of these dialing stages into bundles with few lines. In such a selection stage, test switching means are provided which respond after the control of free outputs via the test wires. For this reason, the test wires between the selection stages on the one hand and the following coupling arrangements on the other hand are provided with switching means which apply the free potential required to address the test switching means.

It is known from the book by R. Führer: “Wahlvermittlungsstechnik”, Fachverlag Schiele and Schön, Berlin 1961, page 174, picture 113, to block the outputs of a dialing stage upstream of a coupling arrangement by switching off the free potential if all the inputs of the coupling arrangement following facility are occupied. It is disadvantageous that this known arrangement can only be used if the switching means supplying the free potential are located in the coupling arrangement or are permanently assigned to the inputs of the coupling arrangement. In addition, a contact must be looped into the line for the free potential.

The object of the invention is to provide a less complex circuit arrangement for blocking outputs of one or more selection stages connected to the inputs of a coupling arrangement if the device following the coupling arrangement can no longer be reached, without interfering with the selection stages and in the wiring of the switching means supplying the free potential , even if they are permanently assigned to the outputs of the electoral levels. This object is achieved with a circuit arrangement according to claim 1.

The advantage of this circuit arrangement is that even if the outputs of the selection stages are freely assigned to the

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Inputs of the following coupling arrangement, e.g. by introducing a distribution distributor between the electoral levels and the coupling arrangement, to which no consideration has to be given to the current and, after changes, to the future assignment. With any routing in the routing distributor, it is thus ensured that only the outputs of the selection stages that are connected to inputs of the following switching arrangement are blocked. Other outputs that are connected to other facilities remain unaffected. Since no intervention in the electoral stages is necessary, this circuit arrangement is very well suited for retrofitting, in particular in connection with dial star devices.

The invention is described for example with reference to Figures 1 to 4. In FIG. 1, the coupling arrangement is designated by K2, which combines many outputs of the selector stage Kl into a bundle with a few lines LI to Lz. These lines LI to Lz connect the outputs of the coupling arrangement K2 to the inputs of a subsequent device, not shown here. The outputs 1 to m of the selection level Kl, of which only the test leads cal, ca2, ca (m - 1) and cam are drawn, lead to a distribution distributor VT. The inputs 1 to n of the coupling arrangement K2, of which only the test leads cel and cen are also drawn, lead to the distribution distributor VT. This distribution distributor VT enables the free assignment of the outputs of the selection stage K1 to the inputs of the coupling arrangement K2, certain outputs of the selection stage K1 being connected to certain inputs of the switching arrangement K2, other outputs of the selection stage K1 being connected to the inputs of other devices not shown here. The outputs of further selection stages, not shown here, can also be brought to the routing distributor, some of which can likewise be connected to the coupling arrangement K2.

One of the relays T1 to Tm is connected to each of the test wire outputs cai to cam, via which the relevant test wire is supplied with the free potential U1. The selection level Kl consists of a number of voters W1 to Wx, of which only the switching arms for the test wires are shown here. One of the test relays PI to Px is connected to each switching arm as test switching device.

In Figure 1 it is assumed that the inputs of the following devices are only connected to the outputs LI to Lz of the coupling arrangement K2. The inaccessibility of this device is therefore synonymous with the occupancy of all outputs of the coupling arrangement K2, i.e. the full load signal VL can be obtained in the coupling arrangement K2 and fed to the blocking devices Sp i to Spn connected to its test wire inputs cel to cen.

If the outputs of the coupling arrangement K2 are still free, the blocking devices Spi to Spn have no effect. E.g. If the output 1, to which the test wire cal is assigned, is controlled by setting the selector W1 to this output by dialing certain digits, the selector W1 can test, i.e. its test relay PI and relay T1 respond, which initiate further functions, not shown here, for establishing a connection. Since output 1 of selector stage K 1 is connected to input 1 of coupling arrangement K 2 in switching distributor VT, it switches its input 1 through to one of its free outputs LI to Lz. If, on the other hand, all the outputs of the coupling arrangement K2 are occupied or cannot be occupied for other reasons (blocking or malfunction), they give a full load signal VL to all blocking devices Spi to Spn, which then block the relevant outputs of the selector stage Kl against assignment. This blocking occurs because the blocking device applies earth potential 0 V to the test other input of the coupling arrangement K2 as a blocking potential. The blocking potential also acts on the relevant output of the selector stage K1 via the routing soldered into the distribution distributor VT and prevents the test relay concerned from responding. The earth potential OV is applied to the test wire either directly or via a resistor. The resistance is dimensioned so that the test relay cannot pick up.

In order to avoid unnecessary consumption of electrical energy, a blocking device only applies the earth potential to the test wire when the relevant output has been controlled by one of the selectors W1 to Wx and the test circuit has been closed via the test relay. The earth potential is applied so quickly that the test relay cannot respond. After the control has ended, i.e. after opening the test circuit, the earth potential is switched off again.

The advantages of the circuit arrangement according to the invention are particularly evident when used on dial star devices. In this case, the dialing level Kl of FIG. 1 corresponds to the line dialing level of a telephone exchange, the dialers W1 to Wx to the line dialers, the relays T1 to Tm to the T relays of the subscriber circuits, the switching distributor VT to the main distributor, the coupling arrangement K2 to the dialing star transmission and the outputs LI to Lz the main dial lines leading to the dial star switch, which is no longer shown here.

In the known selector devices, the line selector outputs are not blocked when there are no more main dial lines. In this case, too, a line selector can check for an output. It then sends out ringing current, but which does not reach the desired subscriber, and It is disadvantageous that the calling subscriber believes on the basis of the ringing tone that the selected subscriber is being called, so the connection is left open for a longer period of time and thus unnecessarily long, possibly expensive, long-distance lines are occupied.

The locking devices according to this invention prevent a line selector from being checked when there are no more main lines free. The line selector then sends out the busy tone and the busy signal, which causes the expensive long-distance lines to be immediately activated. The locking devices are installed in or near the dial star transmission and connected to their test wire inputs. This enables easy installation without interfering with the existing line selector groups and subscriber circuits.

In Figure 2, an embodiment of a locking device according to claim 9 and the test circuit of a selector W1 is drawn in detail. If the outputs of the coupling arrangement K2 are still free, they emit a potential via the line VL which corresponds to the earth potential 0 V. The inverting input (-) of the operational amplifier Ici has a negative potential compared to the non-inverting input (+). So there is earth potential at its output, because it has an earth potential of 0 V on the one hand and the voltage - U2, e.g. - 6 V, is supplied. The transistor Ts 1 is blocked. There is a potential on the test wire cel that corresponds to the operating voltage - U1 e.g. —60 V, corresponds to the fact that the resistance R1 and the input resistance of the coupling arrangement K2 are large against the resistance of the relay T1.

If a voter of the electoral level Kl, e.g. Wl, controlled to the output shown here with the test wire cal, after closing contact h the relay PI can respond via its windings I with 60 £ 2 and II with 1000 Q. The contact p of the relay PI short-circuits the winding II. This prevents someone else's test relay from opening

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can address this output of the set selector.

If no outputs of the coupling arrangement K2 are free, they apply a negative potential to the line VL as a full load signal. The resistors R1 and R2 are dimensioned so that when the test circuit is open, the potential at the inverting input (-) of the operational amplifier Ici is negative compared to the potential at the non-inverting input (+). Its output therefore remains at ground potential and the transistor Ts 1 remains blocked. If a voter, e.g. If W1 is set to this output, the potential at the test wire cal is raised to approximately -30 V after contact h is closed. As a result, the potential at the inverting input (-) of the operational amplifier Ici becomes positive compared to the potential at the non-inverting input (+), its output assumes negative potential, and the transistor Tsl is controlled to be conductive. Since the resistance R3 is relatively small, the potential on the test wire cai is raised to such an extent that the relay PI cannot respond. The locking device is in the locked state.

After opening the contact h, the potential at the test wire cai drops so far that the potential at the inverting input (-) of the operational amplifier Ici is again negative compared to the potential at the non-inverting input (+) and the transistor Tsl is thereby blocked again. The locking device is again in the non-locking state.

Switching means for current limitation and safe blocking (resistors, diodes) can be inserted between the output of the operational amplifier Ici and the transistor electrodes.

In the circuit arrangement according to FIG. 2, a change in potential on the test wire is evaluated as a criterion for switching back to the non-blocking state. This has the disadvantage that the circuit arrangement for each of the various dialing systems must be dimensioned specifically for reliable evaluation, which leads to an undesired variety of types. The development according to claim 10 avoids this disadvantage and enables the construction of uniform locking devices which can be used in all customary switching systems.

The basic function is explained with reference to FIG. 3. G is the common pulse generator of the many blocking devices Spi 'to Spn'. The further details correspond to those of FIG. 1. The selection stage K1 has been omitted, it also corresponds to that of FIG. 1. The pulse generator G sends pulses to all locking devices Spi 'to Spn' at regular intervals, as a result of which the locking devices in the locked state in be moved to the non-blocking state. The locking devices that are connected to a still activated test wire switch back to the locked state before the test relay concerned responds. The other locking devices remain in the non-locking state.

The development according to claim 11 enables use in dialing switching systems in which after checking a voter, i.e. after the test relay has responded, the application of earth potential to the test wire for undesired functions, e.g. Counter suppression or triggering the connection.

In Figure 4 an embodiment of a locking device is drawn according to claim 14. The electoral level K1 has not been shown, the vein cal is followed by the same arrangement as shown in FIG. 2. The operating voltages U1 and U2 and thus also the potentials which arise on the test wire in the various operating states, as well as the resistor R3 and the functions of the transistor Ts1, correspond to those from FIG .

Since the blocking device should only be effective in a test circuit with high resistance, it is set up for evaluating 2 thresholds of the test wire potentials. The operational amplifier Ic2 evaluates the first threshold, which is exceeded when the test circuit is closed, with the voltage divider comprising the resistors R6 and R7. The second amplifier, which is exceeded after checking a selector (low resistance of the test relay), is detected by the operational amplifier Ic3 with the resistors R3, R9 and RIO.

The resistors R4 and R5 and the potential on the line VL in the case of no full load are selected such that the potential at the non-inverting input (+) of the operational amplifier Ic3 is always negative compared to the potential at the inverting input (-). As a result, the output is at a potential that corresponds to the operating voltage - U2. The resistors R6 and R7 are dimensioned such that the diode Gr2 is always conductive at all possible potentials on the test wire cel and thus the negative potential of the output of the operational amplifier Ic3 is also at the inverting input (-) of the operational amplifier Ic2. In contrast, the output signals of the pulse generator G are always positive, the output of the operational amplifier Ic2 is consequently at ground potential 0 V and the transistor Tsl is blocked. In the event of no full load, the locking device always remains in the non-locking state, regardless of the potential on the test wire.

In the case of a full load, the potential on the VL line is positive compared to the potential in the case of a non-full load. The resistors R9 and RIO are dimensioned so that if the second threshold is exceeded (selector has checked, low resistance of the test relay), the potential at the inverting input (-) of the operational amplifier Ic3 is positive compared to the potential on the line VL under full load. The output remains at negative potential as in the case of a non-full load and the locking device in the non-locking state. The existing call connection is not affected.

However, if the test circuit is still open in the case of full load or is closed via the high resistance of the test relay, the potential at the inverting input (-) of the operational amplifier Ic3 is negative compared to the potential on the line VL in the case of full load. The output assumes ground potential, the diode Gr2 is blocked and a potential dependent on the potential of the test wire can form at the inverting input (-) of the operational amplifier Ic2, so that the exceeding or falling below the first threshold can be evaluated.

The resistors R6 and R7 as well as the potential at the output of the pulse generator during the breaks are coordinated so that when the test circuit is open and the diode Gr2 is blocked, the potential at the inverting input (-) of the operational amplifier Ic2 is negative compared to the potential at the non-inverting input (+ ) and thus the transistor Tsl is blocked. After closing the test circuit, i.e. after exceeding the first threshold, the potential at the inverting input (-) is positive compared to the potential at the non-inverting input (+), the transistor TS1 is turned on, thus blocking the test wire. The voltage drop across the resistor R3 causes the potential at the inverting input (-) of the operational amplifier Ic3 via the resistor RIO to cause the potential at the inverting input (-) of the operational amplifier Ic3 to remain negative with respect to the potential of the full load signal VL.

The output potential of the pulse generator G during

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of a pulse is chosen so that it is always positive with respect to the potential at the inverting input (-) of the operational amplifier Ic2. The transistor Tsl is blocked during each pulse. The pulses are so short that a test relay cannot respond due to its delay.

After opening the test circuit, the transistor Tsl remains conductive until the next pulse of the pulse generator G, is, as described above, blocked during the pulse and then remains blocked.

In some telephone switching systems, there are further, initially short-circuited relays in the test circuits. The short circuit of such a relay is only released when the called subscriber reports.

Due to the inductance of this relay, the second threshold is briefly fallen below. A response of the locking device must be prevented. This causes the negative feedback shown in dashed lines in FIG. 4, consisting of the resistor R8 and the capacitor C1. This negative feedback also prevents the blocking of those test wires whose assignment has caused the full-load signal.

• The resistor R5 serves to limit the current. It can be omitted if the current from the operational amplifier Ic2 is sufficiently limited. The resistor R4 and the diode Grl serve to safely block the transistor Tsl. They can also be omitted if the blocking is otherwise ensured.

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Claims (14)

652 549 PATENT CLAIMS 1. Circuit arrangement for telecommunication switching systems for blocking the outputs of one or more selection stages, which are connected to the inputs of a following switching arrangement, with the aid of a full-load signal, which is generated when a device following the switching arrangement is not available, with switching means on the test wires between the selection stage and the switching arrangement for supplying the potentials characterizing the free state, and in the selection stage test switching means are provided which, after switching through coupling points, evaluate the potentials on the test leads and respond in the presence of free potential, characterized in that the test lead inputs (cel to cen) of the coupling arrangement ( K2) a blocking device (Spi to Spn) can be connected, by means of which the test wire inputs (cel to cen) can be blocked in the case of a full-load signal (FIG. 1). 2. Circuit arrangement according to claim 1, characterized in that the connection to the free test wire inputs. 3. Circuit arrangement according to claim 2, characterized in that the test wire input is driven. 4. Circuit arrangement according to one of the preceding. Claims, characterized in that the blocking device is a threshold switch which applies blocking potential to the test wire input (cel) when a first potential threshold is exceeded or undershot when the test wire input is activated. 5. Circuit arrangement according to claim 4, characterized in that the blocking takes place before the test switching means (PI) responds. 6. Circuit arrangement according to claim 4 or 5, characterized in that the blocking potential is selected such that the response voltage of the test switching means (PI) is undershot. 7. Circuit arrangement according to claim 4, 5 or 6, characterized in that the voltage change occurring at the end of the control of the test wire input (cel) leads to the lifting of the blocking. 8. Circuit arrangement according to claim 7, characterized in that the blocking device (Sp) is a network with a negative resistance characteristic. 9. Circuit arrangement according to one of claims 4 to 8, characterized in that the blocking device (Spi) consists of a transistor (Tsl), the collector with the test wire (cel) and the emitter via a resistor (R3) with earth potential (0 V ) is connected between the collector and emitter a voltage divider consisting of two resistors (RI, R2), the tap of which is connected to the inverting input (-) of an operational amplifier (Ici), the output of which is connected to the base of the transistor (Tsl) and that the non-inverting input (+) of the operational amplifier (Ici) is supplied with the full load signal (VL) (FIG. 2). 10. Circuit arrangement according to one of claims 4 to 7, characterized in that the blocking device (Sp 1 ') is switched at short intervals by the pulses of a pulse generator (G) from the blocking to the non-blocking state so that the test switching means (PI) does not respond, and that after the activation end, the locking device (Spi ') remains in the non-locking state (Fig. 3). 11. Circuit arrangement according to claim 10, characterized in that the blocking comprises only the free test wire inputs. 12. Circuit arrangement according to claim 11, characterized in that the blocking does not take place if a second potential threshold is exceeded or undershot by occupying a test wire input. 13. Circuit arrangement according to claim 12, characterized in that when the blocking potential is applied, the exceeding or falling below the second potential threshold is not evaluated. 14. Circuit arrangement according to claim 13, characterized in that the blocking device (Spi ') consists of a transistor (Tsl), the collector of which is connected to the test wire (cel) and the emitter via a resistor (R3) to the ground potential (0 V) is that between the test wire (cel) and earth potential (0 V) there is a first voltage divider (R6, R7), the tap of which is connected to the inverting input (-) of a first operational amplifier (Ic2), the non-inverting input (+) is connected to the output of the pulse generator (G) that the output of the first operational amplifier (Ic2) is connected to the base of the transistor (Tsl) either directly or via a resistor (R5) and / or a diode (Grl), that a second operational amplifier (Ic3) is provided, the non-inverting input (+) of which is loaded with the full-load signal (VL), the inverting input (-) of which is tapped from a second one, between the test wire (CEI) and the center r of the transistor (Tsl) voltage divider (R9, RIO) is connected and that the output of the second operational amplifier (Ic3) is connected via a diode (Gr2) to the inverting input (-) of the first operational amplifier (Ic2) (Fig. 4).