DK141590B - Troubleshooting arrangement for use in cross-networking. - Google Patents

Description

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\ Ra / HD PUBLICATION 141590 DENMARK (s "int.ci.! H ot" § 3/22 (21) Application No. 256/68 (22) Submitted "Jan 24, 1 9 ^ 8 (23) Inadmissible 24 Jan 1968 (44) The application was made and _ 1 ηΑΠ seed poultry seamstress unpublished on April 2, I April I THE DIRECTORATE OF THE PATENT AND TRADEMARKETS <* "Priority be" «« get date.

Jan 25 1967 # 67010554 NL

(71) INTERNATIONAL STANDART ELECTRIC CORPORATION, J20 Park Avenue, New 7ork, N.Y. 10022, US.

(72) Inventor: Hans Helmut Adelaar, Brasschaatse lei 1, Kapelleribos, BE: Jan Van Goethem, 75, Volhardingstraat, Antwerp, BE: Marcel Art = hur Van Brussel, 51 United Natislaan, Hoboken, BE.

(74) Full time during the proceedings:

Hofman-Bang & Bout patent bureau .__ (84) Troubleshooting arrangement for use in cross-networking.

The present invention relates to a troubleshooting arrangement for use with intersection networks consisting of a coordinate system of intersections, each comprising a relay coil, a terminal contact for this relay and a marking diode so interconnected that, by applying a marking voltage to the relay winding in series with the diode, pulls the relay, thereby allowing marking voltage to be applied to a subsequent switching step through the terminal switch, wherein all marking diodes are multiplied together in a common marking conductor.

2 141590 In such networks, a short circuit in the event of a marking diode failure, if the junction is part of a holding connection, transmits the relay connection voltage through the shorted diode to all the diodes multiplied thereto. If the network inputs in this situation are biased by a positive voltage to indicate that when the junctions are not included in a connection, they are available for establishing a new connection, all switching connections associated with the previous step will assume a negative voltage which indicates that they are busy if the impedance through which the positive bias is applied is substantially greater than that found in the holding connection. This means that a new connection cannot be established until the one containing the failed intersection is disconnected.

By changing the bias of the coupling connection, ie. by using a negative voltage, all the coupling connections associated with the previous coupling step can be avoided when a selection diode is shorted.

But in that case, when the fault element is connected to a holding circuit, the marking conductor corresponding to a particular output of all the contacts in one step will get such a voltage that it will simulate a marking state, with the result that by a new connection against an arbitrary output marked by some marking conductor different from the one to which the defective diode is connected will become two diodes conductive and affect two junctions, whereby a double connection will result.

The object of the present invention is to mitigate these disadvantages by means of an arrangement in which cross-linked diodes can be easily found and the faults are rectified in a simple and effective manner.

This object has been found to be attainable by a troubleshooting arrangement peculiar as specified in the characterizing part of the claims.

3 141590

The invention will now be explained in more detail with reference to the drawing in which: FIG. Figure 1 shows a four-stage switching network to which the error-detecting and error-correcting circuits of the invention are connected; 2 is a coordinating coupling step which is part of the circuit of FIG. 1, FIG. 3 shows a circuit for biasing the connecting links in the circuit of FIG. 1 with a positive voltage indicating that they are available and, fig. 4 shows a circuit for biasing the connectors of FIG. 1 with a negative voltage indicating that they are not available.

FIG. Figure 1 shows a four-stage switching network enabling connections between any of 1024 extensions with any of 128 inputs. The outputs may be telephone line circuits, while the inputs may be telephone line circuits. When a connection is provided, a line disconnect relay Cor in connection with a negative battery voltage will be affected by earth supplied through a terminal contact j in a connection circuit and passing through a decoupling diode GJ in the connection circuit and the four switching stages designated A, B, C and D. which, as assumed, each includes a number of junctions with each a relay coil, an associated terminal contact, and a marking diode.

In order to provide a connection between a predetermined input and a predetermined output, a positive battery voltage must be applied to one of the 128 contact inputs of the coupling stages D, of which there are a total of 64, each with two inputs. This positive voltage is applied by closing the switch m to four intersection relays Dr, and a marking voltage equal to ground is applied to a multiple marking wire through a special marking contact md and a diode GD. Through the terminal contact dr, the coupling process is continued in the coupling steps C, B and A until the closure of the terminal contact ar causes activation of the desired switching relay Cor.

FIG. 2 shows one of the 64 coordinate systems constituting the coupling stage B, and it is assumed to contain 32 junctions, of which only four, containing the relays Br11, Br14, Br81 and Br84, are shown together with their associated terminal contacts and marking diodes. There are four b-circuit inputs designated b1-b4 and 8 a-circuit outputs designated al-a8, to which access is secured when a cross-point relay Brll is affected and terminates its final switch contact Brll. The marker leader ml is multiplied to the junctions and has ground voltage.

If a marking diode in connection with this circuit, for example GB11, is shorted, the voltage on the circuit b1, as will be seen in FIG. 1, be a negative voltage transmitted to the marker conductor ml.

The circuit FD fig. 1 exists for each of the 16 + 8 + 4 + 4 multiple marker wires connected to a common detector DET. As shown, the multiple marking wires on the side of the marking contacts that away from the marking ground are blinded through a decoupling diode, ie. the diode SA of the multiple marking wire shown connected to a marking contact ma, to the terminal of the detector THAT which is away from ground, through a switching contact detO belonging to a relay not shown which is included in this detector.

Now suppose that the relay Br11 in FIG. 2 is actuated and included in a holding connection of FIG. 1 between ground and negative battery voltage at the interrupt relay Cor, whereby a diode GB11 is shorted to supply ground through the detector impedance, the switching contact itO, and the diode SB is polarized opposite to the short-circuited marking diode GB11, whereby the diode comes into contact with the final contact brll. Since a holding voltage ground is applied through the terminal contact j to the relay Dr on the right side of the holding connection, if the impedance of the detector has a sufficiently low value, all three relays Brll, Cr and Dr will be shorted and correspondingly all three relays will be tripped. which results in the release of the remaining relays Ar and Cor which are included in the holding connection.

From this moment, the short-circuited marking diode GB11 cannot transmit negative voltages to the multiple-marking conductors because the connection containing this fault junction is tripped. After the trigger, the ground potential provided by the detector DET means that the voltage on the circuit b1 is raised sufficiently, ie. sufficiently close to ground, relative to the negative bias of FIG. 4, to cause an artificial recording of this circuit, whereby the latter can no longer be selected until the error has been corrected.

However, a more complicated case occurs if the faulty intersection does not itself form a holding connection, but if this is the case for another intersection in connection with the same input, such as the relay Br81, which is further connected to the circuit bl. In this case, if a holding connection between b1 and a8 is established through the winding of the relay Br81 in series with a terminal contact br81, the current supplied from ground through the detector DET will reach the circuit b1 through the 0, SB, ml, the short-circuit diode. GB11 and the winding of the relay Brll. This additional current path will increase the holding current flowing through the affected relay Br81 and the affected relays Ar and Cor of FIG.

1. On the other hand, it will reduce the liol flow through the relays Cr and Dr. In this way, the states of the relays on the left side of the fault location are affected in principle, and i.e. Br81, AR and Cor, not but with respect to the relays on the right side of the holding connection, and ie. the relays Cr and Dr are two options: X) The holding current in the right part of the holding connection is still sufficient to hold this, Y) The holding current frame in the right part of the holding connection is no longer sufficient to hold this.

141590 6

For the purpose of flowing through the faulty junction, and i.e. the relay winding Brll, which is equal to the sum of the current increase in the left part and the current decrease in the right part, there are also two options: x) The fault current is insufficient to affect the faulty junction, y) the faulty junction is affected and ends its holding contact brll to the connection circuit al.

We will now look at the four combinations of these two pairs of options, and per. By definition, Xx will not cause any effective interruption to an established connection that would normally be triggered at the end of a conversation.

In this case, the case Yx will automatically occur in a transient manner because reopening of the terminal contact j will be followed by a release of the relays Dr and Cr.

At that moment, the state Yy will automatically enter because the current supplied from ground by the detector DET passing through the short-circuited marking diode GD11 will flow through the relay winding Br11 at the failed intersection point in series with the affected intersection relay Br81, thereby stay connected in series with the other relays AR and Cor.

Thus, following the effect of the faulty intersection relay Br11 on closing its terminal contact br11, a voltage greater than the negative battery voltage will be generated corresponding to ground voltage on the circuit al. If this α-circle is not included in another connection, it will be artificially absorbed and thus no credit will be used again. If the circuit is already part of another connection, ie. is connected to the circuit b4 through a terminal contact brl4 and the winding of the intersection relay Brl4, the presence of this earth voltage on the circuit as already explained will cause the failure of the relays on the right side of the connection, ie. the intersection relay Brl4 7 141590 pg the relays Cr and Dr included in this connection through the circuits a1 and b4.

Furthermore, if the faulty junction turns out to be in the coupling step A, when this is affected in the manner described above, regardless of whether the interrupt relay Cor is affected or not, and that is. regardless of whether the line circuit is free or busy, influencing the faulty junction Ar by connecting a contact scar will add ground to the interrupt relay and always affect this.

Accordingly, while the error detecting circuit FD of FIG. 1 will prevent a complete interruption of telephone traffic, nevertheless the aforementioned case Yy leading to the influence of the faulted intersection will cause one or two partial roads extending from the faulted intersection to the left, and each contains an affected interrupt relay 1 line circuit, is maintained. In such a case, the corresponding lines will be blocked, ie. that they can neither call nor can be called. In addition, apart from this undesirable state, the end of a grounding voltage to the conductor ml is a permanent fault-marking state which in turn can cause dual connections to occur in the manner explained above.

Finally, we will look at the fourth case Xy, viz. the case where the holding current in the right side of the holding connection is sufficient to hold the connection, but where the current through the faulted junction is also sufficient to effect its influence. Hereby, when a connection established through bl and a8 remains maintained, a path is connected from bl to all through the winding in Brll in series with a terminal contact brll, and this can result in a double connection if al is already part of an established connection .

But in all cases, when the connection containing b1 and a8 is released due to the opening of the terminal contact j in FIG.

1, the above-mentioned case Yy will arise again.

8 141590

For the state provided in the latter case, a current detector DET is provided which, when responding to a fault, i.e. on a short-circuited marker diode, it breaks down all existing connections through the network and completely prepares for this. This can be done manually on the basis of an alarm delivered from IT, or it can be done automatically. As shown in FIG. 1, this is accomplished by an alarm provided by a monostable device in the detector by temporarily interrupting ground voltage provided through the latter by a switching contact itO and, on the other hand, by four terminal contacts det1 / 4 of the same monostable relay means. a negative battery voltage is applied to four multiple marking wires in the coupling stage C. In all established connections, the relays Cr and Dr will be short-circuited, whereby all existing connections will be disconnected. The final disconnection of all existing telephone connections is a serious drawback, but as this case will be very rare, it can be considered a minimal accident in relation to the danger of an uncontrolled number of dual connections.

Once the switching device in detector DET has performed its function described above, the switching contact detO will be closed again while the terminal switch detl / 4 is reopened, after which the repaired switching network is immediately ready for use. In reality, only the circuit is artificially occupied and can be used again, so there is no danger that the same undesirable situation will arise again. There will then be plenty of time to locate and replace the short-circuited components. It will be advantageous after the automatic switching means has opened and closed the "it" contacts, that the detector DET remains in a holding state until it is reset manually after failure, ie. after the short-circuit marker LED GB11 has been repaired. In order to facilitate the location of the error component that is common in such networks, interrupt jacks may be provided in all or most of the branches of each selection wire. Obviously, the automatic detection device will be particularly desired in unattended telephone exchange so that the connections can be immediately resumed after network degradation and without waiting for maintenance to take place.

However, an alternate fault detection means may keep the circuit running at all times, although this occurs on the basis of a diminished level of service. In this alternative solution, in the worst case, overcrowding will only take place during peak hours if an error occurs at this time. In this arrangement, a detector DET must still be connected away via decoupling diodes such as SA to various multiple marking conductors, but in this case the impedance of the detector must be relatively large instead of relatively small for the purpose of supplying ground potential.

In fact, such an alternative is that multiple marking threads, like the eight marking conductors ml to m8 in the coupling step B of FIG. 2 is divided into at least two parts as shown in FIG. 2 by two short lines crossing these conductors such that, for example, the multiple marker conductor ml serves only the junctions of FIG. 2, which leads to the circuits b1 and b2, the first of which is shown, while a separate multiple marking conductor m ^ would serve the junctions connected to the remaining circuits, and i. circuits b3 and b4, only the last of which is shown. Thus, there will now be a total of 16 multiple marking conductors in the switching stage B, and a corresponding division of the multiple marking conductors would occur for all the other switching stages A, ·, C, D. * -

In this alternative, the positive circuit biasing arrangement of FIG. 3 to indicate the availability of the circuit. In such a case, and if a marking diode GB11 in FIG. 2 is short-circuited and if this junction forms part of a holding connection or if the associated bl circuit is used in such a connection, the negative voltage which must necessarily be found on the circuit b1 thus provides a negative voltage on all the b-circuits. connected via a cross-point relay in series with a multiple diode marker diode ml. This could in fact be allowed due to the relatively high impedance of the detector DET which would not affect the transmission of such a negative voltage. However, only a portion of the b-circuit in the entire switching network will be marked as artificially occupied due to this negative voltage, and all remaining b-circuits connected to the multiple marking wires Ί ft m to m will not receive this artificial recorded voltage.

Accordingly, by dividing the circuits into two parts, for example, half connection points, half c circuits, half b circuits and half a circuits, these halves would be available in case of failure so that some service can still ensured. Obviously, by dividing into more than two parts, the traffic-carrying capacity of the entire network will be reduced. On the other hand, the current flowing through the relatively high-impedance detector DET against the negative voltage through a short-circuited diode will be sufficient to cause DET to respond, thereby causing an alarm to be identified. short-circuit diode and its replacement;

It is to be understood that the circuit of FIG. 1 shows only one way in which the error-detecting and error-solving circuits of the invention can be provided. There are several modifications and additions associated with the network shown. For example, the dotted line connection in the positive voltage marker branch on the right side of FIG. 1 contain not only a marking contact such as m, but also transistor couplers for providing voltage or closure of such a contact and for removing it after opening it in order to avoid such relay contacts as m establishing or breaking a current path.

In addition, a constant current regulating means may be inserted into the branch. In addition, while the c-circuits have been shown to be connected only to two connecting circuits and, in particular, to one side of such connecting circuits, the same coupling step D can of course be used to provide a path between opposite sides of the connecting circuit and the c-circuit, in which case the number of junctions in the coupling D become twice as large, and if the same marking contact m is used for the input side and the output side of the circuit, where separate marking contacts md are used for such input and output

Claims (3)

1. Troubleshooting arrangement for use in connection with intersection networks consisting of a coordinate system of intersections, each comprising a relay coil, a terminal contact for this relay and a marking diode so interconnected that by applying a marking voltage to the relay winding in series with the diode, the relay draws marking voltage can be applied to a subsequent switching step through the terminal switch, wherein all marking diodes are multiplied together in a common marking conductor, characterized in that each junction point is connected to a test voltage source via a common detector (DET) with an impedance value sufficient to allow a short-circuit diode connected to a cold connection to send a voltage different from the test voltage to the marking conductor. Troubleshooting arrangement according to claim 1, characterized in that the test voltage is selected so that the holding voltage source and the sample impedance have such a relatively low value that a short-circuited diode connected to a holding connection short-circuits at least one of the relay winding herein and thereby causes tripping. of the compound. Troubleshooting arrangement according to claim 1, characterized in that the intersections that at each coupling stage give access, when influenced, to a predetermined coupling output, are divided at least into two groups whose diodes are multiplied