DE2201330C3 - Fault location arrangement for 4-wire communication systems - Google Patents

Description

The invention relates to a fault location arrangement for 4-wire communication systems,

in particular carrier frequency or PCM line equipment, for remote testing of a number of consecutive amplifier sections, their intermediate amplifiers be remotely fed with constant direct current from a terminal.

The German patent specification 1187 274 - 21a2-41 / 07 describes such a fault location arrangement in which to initiate the remote test as a control signal! in the feeding terminal the remote feed current is interrupted a defined short time, whereupon in each Repeater a loop closure of both the remote feed and the signal path between the output of the outgoing from the feeding terminal and the single-gas of the incoming Amplifier is produced and when the remote feed current returns, these loop closures are staggered in time can be canceled one after the other, and at the% 'on of the feeding terminal select this Time a test signal is sent out and received again in the opposite direction and from this received signal and the increase in the supply voltage in the chronological successive cancellation the loop closures a criterion for the function of the repeater and the location of a fault will.

In Fig. 1, such a fault location device according to German Patent 11 87 274 is shown in principle. To create the loop closures in the event of a supply current interruption and their delayed cancellation when the remote supply current returns, relays RL with break contacts are used which are delayed when the supply current is interrupted, and their contacts then create the loop closure. Since the relays are constantly energized during operation, the power they draw constantly consumes power. Added to this is the electricity that has to be applied to generate a sufficiently high dropout delay. In the example described, two further current paths were parallel to the amplifier to be fed, one of which consisted of the series connection of the relay winding with the pill resistor of a thermistor and the other of the series connection of a Zener diode with the heating winding of this thermistor. Since the current strength of 50 mA is internationally fixed for remote supply with constant direct current, any additional supply power requirement in an intermediate amplifier can only be achieved by increasing the supply voltage. However, since the level of the total supply voltages is limited for safety reasons, each additional power consumption reduces the number of intermediate amplifiers to be supplied by a supply chain. In addition, if one of the delayed relays fails, a loop is always formed in the affected intermediate amplifier and the amplifier chain for the transmission of useful signals fails.

The present invention now has the task of designing such a fault location arrangement in such a way that that the additional feed energy required for them is as low as possible and that it is a mistake one element used in this case, if possible, only a disturbance of the fault location device itself, but not the transmission of useful signals.

According to the invention, with such a fault location arrangement, the set object is achieved by that a switching device is provided in each intermediate amplifier, which the feed path in the event of an interruption in the supply current disconnects and after the return of the supply current it switches through again with a delay that this Switching device is a monitoring device in parallel, which when the supply current returns until the delayed Switching through the switching device responds, and that this monitoring device at Address the loop closure of both the remote feed and the signal path

The invention will now be described in detail with reference to the figures. It shows

F i g. 1 the principle of the fault location arrangement already described according to DT-PS 11 87 274 as a block diagram,

F i g. 2 the principle of the fault location arrangement according to the invention as a block diagram,

F i g. 3a to 3d principle and exemplary embodiments of the ι .. ^c i g. 2 switching device S used,

I- i g. 4 shows a block diagram of the fault location arrangement according to the invention,

F i g. 5a and 5b two examples of the in FIG. 4 time circuit L used,

F i g. 6a and 6b two examples of the in FIG. 2 and 4 used monitoring device K,

F i g. 7 a realization of the fault location system according to the invention for a PCM line as a block diagram.

In the case of the in FIG. Fault locator assembly 2 according to the invention is illustrated with respect to the described by the DT-PS 11 87 274 (F i g. 1) substituting greatly on delayed relay RL through the parallel circuit of a switch device S having a monitoring device K. In normal operation, the switching device S is switched through and there is only a small residual voltage to which the monitoring device K does not respond. If the remote feed current is now interrupted for a predetermined time in order to initiate the remote test in the feeding terminal, the switching device 5 blocks and interrupts the remote feed path. Even after the remote feed current has returned, the switching device 5 remains blocked for a predetermined time until it switches through again. During this time the remote feed path is now only closed via the monitoring device K , which responds to the remote feed current flowing through it and establishes the loop closure of the remote feed path and the signal path with its contacts ki and k2. The contacts ki and kl can be contacts of a relay, but also semiconductor switching paths of an electronic switching device. During the response of the monitoring device K , the following intermediate amplifiers are no longer fed remotely by the loop closure in the remote feed loop, while the loop closure of the signal path causes the output of the amplifier directed from the feeding terminal to the input de; Amplifier in the opposite direction is connected so that a test signal sent by the terminal is transmitted back to the terminal and can be examined there. By measuring the remote feed voltage reduced by the loop of the remote feed loop in the feeding terminal, the position of the intermediate amplifier that is currently forming the loop and thus the position of a possible error can be determined. If the Schalteinrich device 5 turns on again, the monitoring device K goes into rest position and the loop locks are canceled, whereupon the next intermediate amplifier receives supply current and there the same

before the process expires.

Compared to the fault location arrangement according to DT-PS 11 87 274, in which the relay RL constantly consumed its excitation current in normal operation and the heating winding of the thermistor required for its strong pull-in delay constantly consumed its heating current, the only additional consumption of supply energy is given by the low residual voltage on the Switching device S in the switched-through state. Solely with the inspection process itself occurs in locked _{switching] 0} device S by the voltage drop at the test facility K an additional Speiseleästungsbedarf on that but a supply chain leads to some, minor exceeding the supply voltage only when checking the last amplifier in normal operation. If the switching device S is designed in such a way that if a component fault occurs it remains continuously switched on, a fault in the fault location device also does not affect the transmission in normal operation, but only leads to the affected repeater being skipped during the test process, which is doubled large increase in supply voltage when the loop of the following intermediate amplifier closes in the supplying terminal. Whether the viewing device S meets these requirements will have to be checked in the description of its implementation examples.

F i g. 3a now shows the principle of the switching device S. A thyristor (SCR) is used as the switching contact, the control electrode of which is controlled by a control device C , which feeds an ignition pulse to this control electrode with a time delay compared to the time at which the supply voltage returns. F i g. 3b and 3c now show different exemplary embodiments for the switching device 5 with different control devices C In FIG. 3b, a unijunction transistor UJT is used in order to obtain the time-delayed control pulse with the aid of the timing element Ci / Ri. The arrangement according to FIG. 3c uses a complementary unijunction transistor for this. while in the according to FIG. 3d a programmable unijunction transistor is used. In the latter case it is possible to use the voltage divider R2 / R3 to influence the response threshold and thus the delay time.

If you talk about rare failures that only occur as a result of manufacturing errors, such as the tearing off of supply lines apart from this, semiconductor components and capacitors show short circuits and resistance interruptions in the event of defects. However, in the event of such errors in the arrangements shown, the thyristor is always triggered or is always conductive even with its own breakdown. This causes a bug in these Arrangements cannot interrupt normal operation, i.e. the signal transmission of the amplifier chain, but only the fault location in the affected repeater puts out of operation what, as already described in the dining terminal on the occasion of the next test carried out is recognized.

Any interruption in the supply circuit in the chain of the following intermediate amplifiers, no matter how short, would cause the formation of the loop, which is staggered one after the other. So that this does not occur, but only takes place after an interruption of the feed current with a minimum duration, the in FIG. The repeater-side part of the fault location device shown in FIG. 2 can be supplemented by a hold circuit H, as shown in FIG. This holding circuit H is applied to the control electrode de; Thyristor SCR continues to supply a control voltage for a certain time after the supply current interruption, so that when the supply current returns during this period of time, the thyristor immediately re-ignites and so the monitoring device K does not respond.

Two realizations of this holding circle H are now in FIG. 5a and 5b shown. The hold circuit H is connected with its terminals d and b parallel to the series circuit of the remote feed terminal of the amplifier with the thyristor SCR, while its terminal c is connected to the control electrode of the thyristor SCR . Be running remote supply current charges a Kondensatoi Cl A4 via a resistor and unijunction transi stors amplifier and thyristor falling Spannunf on. In the variant according to FIG. 5a is parallel to the diode DX a relay RL \, which picks up when the supply current is interrupted by the discharge current of the capacitor G with the diode DX blocked and whose contact r \ then applies the capacitor potential to the control electrode of the thyristor SCR , so that it remains conductive as long as Capacitor Cl a sufficient holding current for the relay ALI and control current for the thyristor SCR is supplied. Only when the charge de; Capacitor Cl has dropped so far, the relay: RLX drops, its contact ή opens and the thyristor SCh blocks, if the supply current has not returned in the meantime.

In the variant according to FIG. 5b is the relay RLi with its contact rX through the PNP transistor Trst , the emitter of which is at the junction of the diode DX with the resistor /?

If feed current flows, the diode Dt leitenc and the transistor is blocked TrsX In Speisestromun interruption the diode DX, the base of transistor receives tial with respect to the emitter negative poten. so that the transistor TrsX switches through and via the resistor /? 4 and its emitter / collector line ke the charge of the capacitor Cl applies to the control electrode of the thyristor SCR. The contradiction R5 in the base circuit limits the base current of the transistor during the charging process. Again, the thyristor SCR is kept conductive as long as the capacitor d still supplies sufficient control to its control electrode. Then it locks if the power supply has not returned in the meantime.

Different variants for the implementation of the monitoring device K will now be described ben. The simplest arrangement is shown in FIG. 6a A relay RL2 is parallel to points a and b of the switching device Ϊ. When the thyristor SCh of the switching device S is triggered, only the forward voltage of the thyristor is applied to the winding of the relay RL2 , which is about 0.7 to 1 V. Relay RL2 designed so that with this voltage there; Relay RL2 certainly does not pick up yet, its contacts remain open.If the thyristor SCR blocks after the supply current has been interrupted, the entire remote supply current flows through the relay winding in the amount of 50mA when the current returns, the relay RL2 pulls ar and its contacts / 2 'and / 2 ² form the loop closure for the remote feed and signal path. The voltage then dropping across the relay winding then simultaneously serves as the supply voltage for the control device C of the switching device S.

If, however, an interruption in the relay winding occurs as a fault, a certain time lies between points a and b , the limit voltage that can be output by the remote supply source, which is greater than the normal supply voltage. This voltage would then also be applied as a supply voltage to the unijunction transistor of the control device C and destroy it. The normal transmission of messages along the route would not be impaired as a result, since, as already mentioned, the thyristor SCR is triggered even if the unijunction transistor is defective. However, it must be felt to be disadvantageous that the failure of a component - interruption of the relay winding - leads to the destruction of another unijunction transistor.

As FIG. 6b shows, this deficiency can easily be remedied by placing a Zener diode in parallel with the winding of the relay RL2. The voltage between points a and b can now not exceed the value of the operating voltage of the Zener diode Zl. Another advantage is that the supply voltage for the control device C is stabilized by this Zener diode Zl, so that the delay times caused by the control device C for the triggering of the thyristor SCR after. Remote supply current recovery can be tolerated more closely.

The diode is now lying in Figure 6b or with the relay winding in series and forward biased Dl serves to compensate for the residual voltage of the ignition thyristor SCR for the relay RL2. Depending on the amount of this residual voltage, several diodes connected in series can be used instead of a single diode.

F i g. 6c shows a further variant of the monitoring device K. parallel to the thyristor SCR is located between points A and turn B is a zener diode Zl, which ignites with blocked thyristor at remote feed current return parallel to this zener diode Zl are the supply voltage inputs of a astabüen multivibrator M, which is locked Thyristör SCR and flowing remote feed current receives a supply voltage equal to the Zener voltage of the Zener diode Zl and thus oscillates as long as this voltage is present, i.e. until the point in time at which the thyristor SCR switches through again. The square wave appearing at the output of the astable multivibrator M is fed to the primary winding of a transformer Tr , which has two secondary windings. The signals from these secondary windings are rectified in rectifier circuits consisting of diode Di and charging capacitor C3 or diode DA and charging capacitor CA , and the rectified voltage applied to charging capacitors C3 and CA serves as a control voltage for the bases of transistors Trs21 or 7> s22, their collector Emitter path serves as switching contact iQ) or ft ¹ . Since suitable astable multivibrators as integrated circuits, e.g. B. in the form of the MC 4024 from Motorola, are available, which externally only a capacitor determining the repetition frequency has to be connected, and also pulse transmitters with 2 secondary windings in the size of an integrated circuit are inexpensive, this fully electronic version of the monitoring device Make K spatially very small. In principle, it must be admitted that if the transistors 7> s21 or Trs22 break down, the normal transmission of messages on the line also fails, since a continuous loop is then formed. However, there are already transistors available today with such a high permissible collector-emitter voltage and very high operational reliability that the occurrence of such a breakdown is not to be feared.

F i g. 7 now shows an exemplary embodiment for the use of the fault location arrangement according to the invention in a so-called intermediate regenerator for a pulse code modulation transmission link for 4-wire operation. Each of the two regenerative amplifiers AfVl and RVl is preceded on the input side by an equalizer £ 1 or £ 2, which compensates for the distortions caused by the transmission line between two regenerators. Since this line section is omitted when the signal closes in a loop, the loop closure with the returning direction may only be carried out after this equalizer £ 2. Here is the control device S according to FIG. 3d, the holding circle H according to FIG. 5b and the monitoring device K according to FIG. 6b is used, the mode of operation of which has already been described in detail, so that a repetition is not necessary. To isolate the potential, the output signal of the intermediate amplifier RVi of a decoupling winding of the output transformer 77 ?! 2 taken from this direction.

For this purpose 4 sheets of drawings 509646/19

j? JS.

Claims (15)

Patent claims: 1. Fault location arrangement for 4-wire communication systems, in particular for carrier frequency or PCM line equipment, for remote testing of a number of consecutive amplifier sections, whose intermediate amplifiers are remotely fed from a terminal with constant direct current, in which the remote test is used as a control signal for the initiation of the remote test In the feeding terminal the remote feed current is interrupted for a defined short time, whereupon a loop closure of both the remote feed and the signal path between the output of the outgoing from the feeding end and the input of the incoming amplifier is established and when the remote feed is restored these loop closings are canceled one after the other in a staggered manner, and in the case of which a test signal is transmitted from the feeding terminal during this time and received again via the opposite direction and S is received from this A criterion for the function of the intermediate amplifiers and the position of a disturbance is obtained from the signal and the rise in the supply voltage when the loop closures are sequentially canceled, characterized in that a switching device (S) is provided in each intermediate amplifier point, which separates the supply path in the event of a supply current interruption and after Stromiviederkehr switches through again with a delay that this switching device (S) is paralleled by a monitoring device (K) which responds when the supply current returns until the switching device (S) is delayed through and that this monitoring device (K) closes the loop of both the remote feed and the remote feed when responding also of the signal path. 2. Fault location arrangement according to claim 1, characterized in that a holding device (H) is additionally provided in each intermediate amplifier point, which prevents the disconnection of the feed path by the switching device (S) in the event of very brief interruptions in the remote feed and only releases this when the interruption of the Remote feed current exceeds a specified period of time. 3. Fault location arrangement according to claim 1, characterized in that a thyristor (SCR) is used as the switching contact of the switching device (S), that this thyristor (SO?) Is blocked by the interruption of the supply current and, when the supply current returns, by one of its Steueranschl'iB, and the time-delayed control pulse generated by a control device (C) is switched through again (FIG. 3a). 4. Fault location arrangement according to claim 3, characterized by the use of a unijunction transistor (UJT) for generating the time-delayed control pulse in the control device (Q (Fig. 3b). 5. Fault location arrangement according to claim 3, characterized by the use of a complementary unijunction transistor (CUJT) for generating the time-delayed control pulse in the control device (C) ( FIG. 3c). 6. Fault location device according to claim 3, characterized by the use of a programmable unijunction transistor (PUJT) to generate the time-delayed control pulse ir the control device (C) (F i g. 3d). 7. Fault location arrangement according to claim 3 and one of claims 4 to 6, characterized in that when the switching device (S) on the monitoring device (K) is blocked by the remote feed current, the voltage of the control device (Q is used as the supply voltage). 8. Fault location arrangement according to claim 2 and 3, characterized in that the holding device (H) has a capacitor (C2) which is charged during operation to the voltage dropping in the intermediate amplifier by the remote feed current that the charge of this capacitor (C2 ) is fed to the control electrode of the thyristor (SCR) and keeps it switched through until the capacitor (C2) is discharged. 9. Fault location arrangement according to claim 8, characterized in that when the supply current is interrupted, the charge of the capacitor (C2 ) is fed to the control electrode of the thyristor (SCR) via the contact of a relay (RLi) and a resistor (R4). 10. Fault location arrangement according to claim 8, characterized in that when the supply current is interrupted, the charge of the capacitor (Cl ) is fed to the control electrode of the thyristor (SCR) via the emitter-collector path of a transistor (Trsi) and a resistor (R4). 11. Fault location arrangement according to claim 1, characterized in that a relay (RL2) is used as the monitoring device (K) , that the winding of this relay (RL2) of the switching device (S) is parallel, and that through its contacts (i2 \ Λ ¹ ) the loop closure of the remote feed and signal path is established. 12. Fault location arrangement according to claim 11, characterized in that the winding of the relay (RL2) a Zener diode (ZX) is connected in parallel. 13. Fault location arrangement according to claim 11, characterized in that one or more forward-polarized diodes (D2) are connected in series with the winding of the relay (RL2). 14. Fault location arrangement according to claim 1, characterized in that the loop closure of the remote feed and the signal path through the emitter-collector paths each of a transistor (Trs 22, Trs 21) takes place that the switching device (S) the supply current inputs of an astable multivibrator (M) lie in parallel that the output signal of this astable multivibrator (M ) controls the bases of the transistors (7> s21 or 7rs22) after potential separation by a transformer (7>) and rectification in rectifier arrangements (Di, C3 or Di, CA). 15. Fault location arrangement according to claim 14, characterized in that the supply current inputs of the astable multivibrator (M) is a Zener diode (ZI) in parallel.