DE943119C - Method and circuit arrangement for registering unsuccessful checks on occupied connection paths in switching systems, in particular in telex switching systems with dialer operation - Google Patents

Description

Method and circuit arrangement for registering unsuccessful checks on occupied connection paths in switching systems, especially in telex switching systems with selector mode The invention relates to a circuit arrangement for registering, preferably counting, the unsuccessful checking of links for occupied Connection paths in switching systems, in particular in telex switching systems with dial-up operation.

Such institutions have, among other things, the task of - certain Subscriber lines the frequency of unsuccessful checks when the Determine the participant in order to take appropriate measures, e.g. B. by assigning a further subscriber connection, the blind assignments of the expensive trunk lines in - Reduce long-distance self-dialing to an economically viable level. One known device of this type used for all line selectors, the output to the participant to be monitored have special additives, which in turn determine how often the busy tone is sent back when this connection is reached got to. The additions required in the form of test lead selectors make this facility expensive and cumbersome to use. Also, the incorporation of these additives makes Changes in the existing office facilities necessary.

Another known arrangement used to count an occupied Connection of its own auxiliary circuit with an auxiliary battery, which is powered by a built up Connection prepared and by switching means that respond in the event of a further assignment is closed. This arrangement is tied to switching systems, the circuitry show a difference between two busy line selectors, one of which is occupied by the connection to be checked and the other by a calling Subscriber busy but not yet switched on to the connection.

According to the invention, the disadvantages outlined are the known Facility eliminated by the fact that the time-limited duration of the impact another link to an occupied connection path in the circuit potential change occurring on the test wire for triggering the registration is made usable. The decrease in the potential changes that can be evaluated for registration of the circuit of the test wire is at particularly easily accessible points on the connection path possible, for example between the connecting links to be checked and the organs, to be checked.

The registration of the checking of connecting links is advantageously carried out on an occupied connection path with identification of the occupancy direction in one preferably a structural unit forming device by depending on the direction and the time sequence of the potential changes occurring in the test circuit during testing Switching means are effective, each of the current occupancy direction Bring the associated registration device to respond, the registration device protect the other direction of occupancy from being influenced.

Additional measures may be required to register the occupancy required depending on the direction of occupancy, if for example at Occupancy of the participant in the outgoing direction of the test circuit completely interrupted will. The test circuit is expediently connected to a certain potential so. when checking a further link that triggers the registration to enable the required change in potential.

To prevent the registration device from responding prematurely during manufacture To prevent a connection, according to the invention, switching means can also be used be provided that the control circuit for the registration device only after subsiding the one at the occupancy, for example, in the incoming direction in the test circuit Bring potential change in readiness to respond.

It is also possible that when testing a further link occurring potential change is different in size, depending on whether the relevant Connection path in the incoming or outgoing direction is occupied. In this case can according to the invention a preferably capacitively coupled to the test circuit Amplifier tubes are provided whose grid voltage is affected by the changes in potential of the test circuit is controlled so that one in the anode circuit of this tube horizontal winding of a relay used to control the registration device is influenced by it.

Another part of the invention is that by special Measures the disturbing influence of the harmonic content as well as the test circuit as well as the voltage source feeding the anode circuit of the amplifier tube is largely suppressed.

In this way it is possible to test a connecting link to an already occupied connection path without any special effort and expense Means conveniently and with great security, indicating the direction of occupancy to register. In addition, the device according to the invention thereby gains. Meaning, that their installation does not result in any changes to the existing office facilities.

Further details of the invention can be found in the hand- i to 5 described embodiment of the invention. In the The drawing shows Fig. I the basic circuit of the last selection stage of a step-by-step selection system during the attempt to seize an outgoing seized subscriber line, Fig. z the basic circuit of the last selection level of a step-by-step dialing system. the attempt to bend an incoming subscriber line, Fig. 3 Voltage-time diagram for the test circuit according to the changes in state a connection according to Fig. i, Fig. q. the voltage-time diagram for the test circuit the circuit arrangement corresponds to the state changes of a connection according to FIG. 2, FIG according to the invention.

In order to allow the special features of the invention to be recognized more clearly, are first explained with reference to FIGS. i and 2, the processes involved in the Play last dial level of a step-by-step dialing system, if a participant cannot be reached because it is already in use in another connection. Figures 3 and q. illustrate in_Fnnm of voltage-time diagrams the potential changes, that arise in the test circuit during these processes.

To set up a connection in the outgoing direction, the preselector VW in FIG. When an attempt is made to seize this subscriber inbound, the P relay of the line selector LW checks the closed U contact for the disconnected test wire and cannot respond. When the u-contact in the test lead of the line selector opens, the test time ends and the line selector signals the busy case to the calling subscriber.

The registration device Rg evaluates to count this busy case according to the invention, the potential change on the test wire during the time-limited Test time off. It applies high-resistance earth to the test wire in order to avoid the during an outgoing Occupancy to give the test lead disconnected from the participant a defined potential. the The processes described remain unaffected. The potential changes that appear on the test wire as a result of changes in the state of the connection, can be seen from the voltage-time diagram of FIG. In the idle state o-i and with outgoing assignment of connection i-2 (via the high-resistance resistor) - the test wire has the potential o volts. When trying to get this connection incoming to assign, the line selector opens and the potential of the test wire jumps at point 2 practically to -6o volts (minus jump). After the end of the fall time of the U relay-related test duration, the potential of the test wire drops again in point 3 back to 0 volts (plus jump).

When establishing a connection in the incoming direction, the P relay of the line selector LW i responds during the test period via the closed u contact in Fig. 2 and its contact P switches to the test wire to the preselector VW with low resistance. The T-relay in the course of this connection has a total resistance of around 9.300 ohms with all series resistors. If another line selector LW 2 tests this existing connection, its test relay P (6o Ohm) with a series resistor of 500 Ohm can be used. Do not respond in parallel to the low-resistance test relay P (6o Ohm) of the line selector LW i due to the existing potential barrier. After the end of the test time, the busy case is signaled to the calling subscriber - The registration device Rg evaluates the relatively small change in potential of the test wire for counting, which results from the parallel connection of the high-resistance P relay of the line selector LW 2 with the low-resistance P relay of the Line selector LW i results during the test period. The potential shifts on the test wire resulting from the changes in the state of the connection are shown in the voltage-time diagram in FIG. illustrated. When the connection oi is idle, the test wire has the potential o volts. At point i, their potential jumps to -55.25 volts with incoming occupancy. When trying to prove this caller is busy on another line selector LW 2, shifts the potential of the Prüfader, in point 2 of -5,565 volts. After the end of the test period, the potential in point 3 goes back to -55.25 volts and falls when the connection is released in point q. on o volts.

By time-controlled switching relays it is achieved that for Counting of busy cases for both outgoing and incoming subscribers in each case only the change in potential occurring during the narrowly limited test period is evaluated, so that incorrect counts due to possible interference pulses or the like. Practically be avoided.

In Fig. 5 the circuit arrangement of an embodiment according to the invention is shown. It essentially consists of a combined relay and tube circuit. The circuit is switched with its input E between the line selector output and the preselector input to the test wire of a subscriber to be monitored for busy cases. The control grid of the intensifier tube Ro i is capacitively coupled to the Prüfader via the input E, and is a high impedance across the resistor W 3 at one fed by the battery selector WB voltage divider W7, WB. A polarized three-winding relay D receives an isolating-side excitation via its winding DoI by the anode direct current of the tube Rö i. The anode direct current of a second tube Rö 2 flows through the winding D II and gives the relay D a bias voltage acting on the character side. The windings DI and D II are symmetrical windings. With the help of the controllable cathode resistor R the anode direct current of the tube Rö 2 is brought to exactly the same value as the anode direct current of the tube Rö i, so that when the circuit is idle the resulting direct current excitation of the two windings DI . - and D II has the value zero. The armature d of the relay D is in the idle state of the circuit under the influence of a strongly isolating excitation of the auxiliary winding D III in the separating position T. In the operating state, the respective position of the armature d is secured by the action of a correspondingly directed excitation in the auxiliary winding DIII. Between the center of the voltage divider W g, W io and input E there is a polarized relay S with a high-resistance winding, the armature s of which is in the separating position T shown in FIG. 5 when the circuit is in the idle state. With its armature s in the separating layer T, the S-relay scans the parallel-connected circuits for a copper-delayed switching relay X on the one hand and for a counting relay Z i that registers the occupied cases of outgoing occupied subscribers on the other hand: In the character position Z, the S-relay switches depending on the Position of the contact xI either the resistor W i2 connected to the input E to earth, or it closes the circuit for the winding I of the J relay via earth. The counting relay Z2, which registers the busy cases of incoming occupied subscribers, is controlled by the armature d of the relay D operated by the amplifier tube Rö i. The switching relays J and K are also pressed in the contact circuit of the D relay. .The contacts of the D-relay are supplied with the plus and minus poles of the telegraph battery TB and voter battery WB connected in series and grounded in the middle.

The mode of operation of the circuit arrangement described above and shown in FIG. 5 is as follows: The rest position of the polarized test relays S and D is the isolating position T shown in FIG when these relays are not energized. In the rest position of a subscriber to be monitored for busy cases, the test wire has a potential of 0 volts via the T-relay in the preselector. At the winding end 2 of the test relay S there are approximately -53 volts due to the action of the voltage divider W g, W io. As long as the test lead carries potentials more positive than -53 volts, the armature of the S-relay is in the separating position T and, as a result of the current reversal in the winding, only places it in the drawing position Z when the test lead comes to a potential more negative than -53 volts. When the connection is in the idle state, the armature s in the separating layer T closes the circuit for the X relay (earth, s in the separating layer T, X relay, -WB). The X relay is energized, so that its contacts xI, xII, xIII and xIV assume the opposite position to that shown in FIG. Contact xI prepares the connection to the relay winding JI, contact xII prepares the connection to the counting relay Zi. Contact xIII has separated the armature d of the D relay from the .. relay J and K. Contact xIV interrupts the circuit via the relay windings J II and K. The relays J and K are therefore not energized. The armature d of the D-relay is under the influence of the strongly isolating-side excitation of the auxiliary winding D III in the isolating position T (-E- TB, kI, W16, DIII, earth), which characterizes the rest state of the D relay.

If the participant establishes an outgoing connection, it turns into a familiar Way its selection out of the zero position and disconnects the earth via the T-relay on the test wire. The S relay continues to receive excitation on the isolating side (voltage divider W g, Wio, S-Relais, Wir, Erde), so that all other relays also have the previously described ones Assume state.

If the test relay P (60 ohms) - of a line selector tries to check its series resistance of _ 500 ohms, the test wire receives practically the potential of - 60 volts via the P relay during the test time, which is limited by the release time of the U relay in the line selector. The test wire has a potential more negative than 53 volts, so that the armature s of the S relay flips over in the Z position of the drawing as a result of the current reversal in the winding. The copper-delayed X-relay has a release time of about i?, O ms and therefore does not release during the test process, which lasts between 50 and 80 ms. The pulse relay J is excited via its winding J i (earth, s in the drawing position Z, JI, -f- TB) and places its contacts iI and iII in the opposite position to that shown in FIG. After the end of the test time, the potential of the test wire jumps back to 0 volts. The S-relay moves back into the separating layer T and switches off the copper-delayed J-relay, which has a release time of about qo ms. When the armature s is placed back on the isolating contact T, the counter relay Zi receives a pulse (earth, s in isolating position T, W13, Z1, xII, iII, kIII, -WB) during the release time of the J relay and registers the occupancy.

During this switching process was triggered in the test circuit depending on the excitation state of the X relay, an influence on the counter Z2 prevented.

If the subscriber to be monitored arrives in the idle state, then the voltage divider from the resistors of the relay P - (6o ohms) in the line selector LW i and the relay T (230o ohms) in the preselector VW gives the test wire a potential of - 58.5 volts . Since the potential of the test wire is more negative than - 53 volts, the S relay puts its armature s in - the character position Z, in which it remains during the entire time of the existing connection. The anchor s has interrupted the circuit of the X relay. After about 10 ms, the X relay drops out, so that its contacts xI, xII, xIII and xIV assume the position shown in FIG. Contact xI switches the resistor W i connected to the test wire? on earth. By connecting. This resistance to the test wire, the potential of the test wire is changed so that a significant increase in the potential change to be evaluated in the test circuit when another connecting element hits the participant in the incoming direction is achieved. This shifts the potential of the test wire from - 58.5 volts to - 55.25 volts. The relay X which has dropped out separates the connection to the counter relay Zi with its contact xII and switches the relays J and K to the armature d of the D relay with its contacts xIII and x IV. The J relay is short-circuited via the armature d in the separating position T , so that its contacts i I and i II are in the position shown in FIG. The K relay is energized (-E- TB, d in separating position T, xIII, iI, K-Relais, -WB ) and places its contacts k I, k II and k III in the opposite position to that in FIG. 5 shown illustration: Contact kI interrupts the excitation of the auxiliary winding D III, which acts strongly on the isolating side, so that from now on the isolating position of the D relay is only determined by the holding excitation of the auxiliary winding D III, which acts on the weakly isolating side (+ TB, d in isolating layer T, W15, DIII, earth). The test relay D is ready to respond.

. If the test relay P of the line selector LW 2 now tries to check the subscriber who is already occupied by the line selector LW: r, the parallel connection of the relay P (56o ohms) to the relay P (6o * ohms) results in the potential of the test wire from - 55.25. Volt shifted to - 55.65 volts (minus jump). This negative pulse is transmitted to the control grid of the amplifier tube Rö i via the capacitor C i. The anode current of the tube Röi is briefly smaller, so that the now predominant excitation of the winding II acting on the drawing side shifts the relay D in the drawing position Z. After the impulse has subsided, the equilibrium between the two excitations in windings DI and D II is restored and the D relay remains in position Z under the effect of its holding excitation (= WB, d in position Z, W 15, DIII, earth ). After about 5o to 8o ms the test time of the line selector LW 2 ends, and the relay P (56o Ohm) is disconnected by opening the contact ü. The potential of the test wire jumps back to -55.25 volts (plus jump). This positive pulse causes a brief increase in its anode current at the control grid of the amplifier tube Rö i. The excitation in winding DI that acts on the isolating side outweighs the excitation of winding D II on the sign side, so that the armature d of the D relay moves back into the isolating position T. During the brief character position of armature d, the J relay was energized via winding II (- WB, d in character position Z, xIII, xIV, JII, + TB). Its contacts i I and i II are switched to the working position. The K relay was energized and was short-circuited by armature d in position Z of the drawing. It has a fall time of about 100 ms and therefore does not fall during the brief character position of the armature d. As soon as the anchor d moves back into the separating layer T. the winding II of the J relay is short-circuited, and the counter relay Z2 receives a pulse (+ TB, d-in separating layer T, xIII, kII, iI, W14, Z2, -WB) during the release time of this relay.

When the connection is released, the potential of the test wire is noticeable o volts. The armature s of the relay S moves back into the separating layer T and closes again the circuit for the X relay. Contact xIII interrupts the circuit of the K relay. K relay drops out and switches the circuit of the with its contact kI Auxiliary winding III of the D relay on. The circuit is again in the idle state.

Incorrect counts as a result of interference voltages or the like are practically not possible, since for counting according to the invention in the pulse sequence of a specific direction, relatively narrow time conditions must also be observed. If z. B. during the occupancy time of an incoming occupied subscriber, the D-relay is switched to the character position Z as a result of a sudden change in battery voltage and döit remains longer than ioo ms, so there is no busy case for registration due to the missing subsequent plus pulse. In such a case, the J relay responds first (+ TB, J II, x IV, x II I, d in the character position Z, - WB). The K relay drops out due to a short circuit across armature d in position Z. about 100 ms and puts the D relay back into the separating layer T via its auxiliary winding D III (+ TB, kI, W16, DIII, earth). However, the counter relay Z2 can not respond when the armature d is moved back into the separating layer T , since its circuit is interrupted by the open contact kII. After about 3o to qo ms, the relay J short-circuited in the separating position of the armature d drops out and the K-relay responds again (+ TB, d in the separating position T, xIII, iI, K-relay, -WB). The circuit is then in readiness for the registration of further busy cases.

Faults that trigger a minus pulse with a plus pulse after about 25 ms or earlier do not affect the counting relays Zi and Z2, since the pulse relay J does not respond during such time periods. In order to largely suppress the disturbing influence of the harmonic content of the voltage source WB feeding the test circuit on the control grid of the amplifier tube Rö i, the control grid of this tube is connected to a voltage via a voltage divider W7, W8 fed from the selector battery WB in conjunction with the capacitor C 6 which - corresponds to the amount and phase of the test wire potential while the connection path is being occupied in the incoming direction.

Unsuccessful attempts at occupancy can also be carried out according to the same principle register certain outputs in all similarly structured pulse dialing stages. If you monitor an output from a number of group selectors is occupied in each case on the last turning step of the remote dial, so can be without Difficulty the »spin-off of these group voters with the recording device according to of the invention count.

Claims (3)

PATENT CLAIMS: i. Method and circuit arrangement for registering, preferably counting, unsuccessful test attempts by connecting links on occupied connection paths in switching systems, in particular in telex switching systems with dialer operation, in which the potential in the test circuit formed by the test wire is changed by occupying a connection path, characterized in that, that the time-limited duration of the change in potential that occurs when a further link hits the occupied connection path in the circuit of the test wire is made usable for triggering the registration. 2. Procedure and circuit arrangement according to claim i, characterized in that the testing of connecting links separately registered on an occupied connection path for both directions of occupancy will. 3. The method and circuit arrangement according to claim i, characterized in that the checking of connecting links on an occupied connection path is registered without marking the occupancy direction. q .. Circuit arrangement according to claims i and 2, characterized in that the registration of the checking of connecting links on an occupied connection path, identifying the occupancy direction, is carried out in a device preferably forming a structural unit, by depending on the direction and time sequence of the in the test circuit when potential changes occurring when checking, switching means are effective, which in each case cause the registration device assigned to the current occupancy direction to respond, but protect the registration device of the other occupancy direction from being influenced. 5. Circuit arrangement according to claims i to q., Characterized in that a certain potential is constantly applied to the test circuit, which is changed in a direction indicative of the existing occupancy when testing a further link on the occupied associated connection path. 6. Circuit arrangement according to claims i, 2, q. and 5, characterized in that a preferably poled, high-resistance test relay (S) with its one coil end (i) of the test circuit and with its other winding end (2) via a preferably fed from the selector battery (WB) voltage divider (W9, W io ) is placed at a potential such that the test relay (S) in the idle state and when the connection path is occupied in one direction according to the existing potentials of the test circuit in a certain, the armature (s) in the separating layer (T), on the other hand, if the connection path is occupied in the other direction and if the attempt is unsuccessful, the test circuit is excited in a certain direction that moves the armature (s) into the character position (Z) according to the potentials of the test circuit present here. 7. Circuit arrangement according to claim 6, characterized in that when the armature (s) flips over from its rest position (T) into the character position (Z) and remains there for such a time that, on the one hand, the delayed response of one of the armature (s) controlled pulse relay (j) via the winding (jz), on the other hand, the dropping of a delayed time evaluation relay (X) influenced by the armature (s) prevents the armature (s) from returning to its rest position (T) during the the release time of the pulse relay (J) is actuated. - B. Circuit arrangement according to claims g. and 7, characterized in that depending on the state of excitation of the time evaluation relay (X) - the response of a polarized test relay (D) which is influenced by the changes in potential of the test circuit and controls the recording device is prevented. G. Circuit arrangement according to Claim 7, characterized in that the time ejector relay (X) has a drop-out delay which reliably bridges the duration of the checking process. ok Circuit arrangement according to one of Claims i to g, characterized by switching means which make the control circuit for the registration device (Z2) ready to respond only after the change in potential occurring in the test circuit during occupancy in the other direction has subsided. . ii. Circuit arrangement according to claim 10, characterized in that when the armature (s) of the test relay (S) remains in the character position (Z) for a certain period, the time evaluation relay (X) drops out, which, depending on this state, has the influence of the Checking another link on the connection path generated in the other direction of the test circuit's potential change on the control circuit of the recording device (Z i) prevents this change in potential from affecting the test relay (D) controlling the recording device (Z2). 12. Circuit arrangement according to claims io and ii, characterized in that depending on the non-excited state of the time evaluation relay (X) of the rest position (T) lying armature (d) of the test relay (D) a delayed time evaluation relay (K). makes to respond; that in this state the interruption of a strongly isolating-side excitation in the auxiliary winding (D: III) of the test relay. (D) causes the test relay () to be activated. "- 13. Circuit arrangement according to claims zo, ii and 12, characterized in that; when the armature (d) of the test relay (D) moves from its rest position (T) to the character position (Z) and remains there for such a time , which on the one hand ensures the delayed response of the pulse relay (J) controlled by the armature (d) via the winding (jII), and on the other hand prevents the drop-out delayed time evaluation relay (K) influenced by the armature (d), the armature (d) when moving back in its rest position (T) actuates the registration device (Z2) during the release time of the pulse relay (j). 1q .. Circuit arrangement according to claim 13, characterized in that the time evaluation relay (K) has a release delay which safely bridges the duration of the checking process according to claims 13 and 1q., characterized in that when the armature (d) of the test relay (D) remains in the character position (Z) for a certain period, the time evaluation relay (K) de-energizes falls, that in this state the armature (d) is in its rest position via the excitation of the auxiliary winding (DIII), which acts on the strongly isolating side. (T) brings back and the control circuit for the registration device (Z 2) is again ready to respond. 16. Circuit arrangement according to claim 15, characterized in that; that when the armature (d) is returned to its rest position (T) by the excitation of the auxiliary winding (D III) acting on the strongly isolating side, the registration device (Z2) is not actuated. 17. Circuit arrangement according to claims io and ir, characterized in that the armature (s) of the test relay (S) in character position (Z) changes the potential of the test circuit via a resistor (W i2) when the time evaluation relay (X) has dropped out, that a substantial increase in the potential change to be evaluated in the test circuit when a further connecting link hits the connecting path occupied in the other direction is brought about. 18. Circuit arrangement according to one of claims ix to 15, characterized by an amplifier tube (Rö i) which is preferably capacitively coupled to the test circuit and whose grid voltage is through. the changes in potential of the test circuit is controlled in such a way that a winding (DI) of the test relay (D) used to control the recording device (Z2) in the anode circuit of the tube (Rö i) is influenced. ig. Circuit arrangement according to Claim 18, characterized in that the test relay (D) has a winding (D II) which is symmetrical in relation to the winding (DI) and through which a direct current of such magnitude and direction continuously flows that the in the windings (DI and D II) effective direct current excitations cancel each other out. 2o. Circuit arrangement according to claim ig, characterized in that to compensate for the influence of the harmonic content and the static voltage fluctuations of the voltage source feeding the anode circuit of the amplifier tube (Rö i) on the winding (DI) of the test relay (D) the direct current flowing through the winding (D II) is preferably the anode current of a tube (Rö 2) that is independent of the amplifier tube (Rö i), one of the tubes (Rö i) has approximately the same characteristics and both of which are operated under the same static operating conditions and with the same voltage sources. 21. Circuit arrangement according to claims 12, 18 and iy, characterized in that the ready-to-respond test relay (D) is influenced by the potential shifts triggered in the test circuit in such a way that its armature (d) by brief condensation current surges in one direction corresponding to the character position (Z), on the other hand, is placed in the separating layer (T) in accordance with those in the other direction. 22. Circuit arrangement according to claim 21, characterized in that the position of the armature (d) determined by the direction of the short-term capacitor current surges after these pulses have subsided, in each case by the action of a correspondingly directed excitation in the auxiliary winding (D III). is secured. 23. Circuit arrangement according to claim 18, characterized by switching means which largely suppress the disruptive influence of the harmonic content of the voltage source feeding the test circuit on the control grid of the amplifier tube (Rö i). 2q .. Circuit arrangement according to claim 23, characterized in that the control grid of the amplifier tube (Rö i) is connected to a voltage via a voltage divider (W7, W8) preferably fed from the selector battery (WB ) in conjunction with a capacitor (C6), which corresponds to the amount and phase of the test circuit potential while the connection path is being occupied in the other direction. 25. Circuit arrangement according to claims 6 and 18, characterized in that the potentials existing in the test circuit according to the respective operating states of the connection path are decreased at easily accessible locations, preferably between the connecting members to be tested and the organs that are being tested. Referenced publications: German patent specification No. 578 40g.