DE3619165A1 - Device for blocking the connection set-up of a telecommunications device - Google Patents

Abstract

A blocking device for telecommunications devices with connection set-up using the pulse dialling method has a first controllable electronic switching element (transistor T2) which bypasses the loop of the telecommunications device and blocks for as long as the voltage present on the connection line is applied to its control input. A delay component (C1, R4, R2, R3) delays the rise of the voltage at the control input of the switching element (T2) in relation to the rise of the voltage present on the connection line when the loop is interrupted during the dialling operation. The control element (T2) is thus through-connected during the dialling operation so that the loop current flows via the blocking device and no dial pulses can be generated. <IMAGE>

Description

The invention relates to an egg on the connecting line A telecommunication device connectable Direction to block the connection establishment in the impulse election procedure according to the preamble of claim 1.

Locking devices of this type serve the user tion of a telecommunications device by unbe authorized persons to prevent. The locking device leaves incoming call signals and speech signals unhindered through, so that long-distance calls or the like. in the usual way se can be received. The locking device however blocks the outgoing election impulses, so that from the blocked telecommunications facility no Ver bonds can be built.  

A known locking device has one in the An end line used relay, which at acti fourth blocking device interrupts the outside line. A ringing pulse placed on the office side in front of the relay sensor actuates the relay for incoming call signals, so that the outside line for the incoming call ge is closed. With this locking device the Call signal voltage damped. The lock also has direction a damping of the outgoing election impulses as well of speech signals. The mechanical relays contacts are subject to wear.

The invention has for its object a lock to create a device that has no mechanical switching contacts and does not cause signal attenuation.

This task is the one with a locking device genus mentioned solved according to the invention by the features of the characterizing part of the patent saying 1.

Advantageous embodiments of the invention are shown in specified in the subclaims.

The locking device bridges the Loop through the telecommunication device controllable electronic switching element. The wheel The input of the switching element is at the connection line tion applied voltage via a delay element  guided. The switching element locks when driving input voltage with that at the connection line applied voltage coincides. ls the Loop of the telecommunication device interrupted chen because e.g. the handset on the telephone is on the control input of the Switching element the full supply voltage of e.g. 60 Volts or in the case of private branch exchanges e.g. 24 volts on. The switching element blocks and incoming call signals are not damped by the locking device or distorted. Is the loop in telecommunications device closed because the handset has been removed is broken, the one on the connecting cable breaks voltage across the loop to about 6 to 17 volts together. In this state, too, this is pending Voltage at the control input of the switching element, so that this locks. The locking device therefore leads not to dampen or distort the speech an incoming call. However, at removed handset generates dialing pulses, so the loop of the telecommunications device each for the duration of the dialing impulses of approximately 60 ms chen. During this period, the full feed span lies voltage of 60 volts or 24 volts on the connecting line and thus over the switching element. Due to the delay However, the control element increases at the control input of the switching element applied voltage within the short duration of the election impulses does not affect the value of the Supply voltage on, so that the switching element switches through tet and for the duration of the election impulses the loop of Telecommunication device shorts. The The loop of the telecommunication device therefore remains closed via the locking device so that none Election impulses can go off. It is therefore not  possible from the locked telecommunications facility to establish a connection.

The delay element can be controlled by a second bridged electronic switching element by the Voltage present on the connection line can be controlled and switches through when this voltage corresponds to the value of the assumes full supply voltage. This ensures that when the loop is unoccupied, e.g. the Handset is on, the delay is ineffective and the incoming call signal pulses do not become one Switch through the first switching element, but without being influenced by the locking device to the Get telecommunications equipment.

Switching elements are advantageously used as switching elements used transistors, in particular MOS field effect transistors due to their high resistance in the Locked state a completely damping-free locking device result.

The delay element is advantageously as RC link trained. The second controllable Schaltele ment is a field effect transistor, in particular a MOSFET connected in parallel with the resistance of the RC-Glie which is switched. Is the field effect transistor through switched, the time constant of the RC delay limb zero. At the gate of the second field fekttransistor is connected to a voltage divider voltage applied to the connecting cable. The tension divider is dimensioned so that the swell  voltage of the field effect transistor is below if the applied voltage when the loop is closed the low value has dropped while the threshold voltage is exceeded and the field effect transistor turns on when the voltage is below broken loop on the high value of the chipboard voltage lies.

The locking device expediently has one Bridge rectifier so that the locking device polarity-independent to the wires of the connecting cable can be connected.

A varistor is preferably used as overvoltage protection between the input connections of the locking device switched. A zener diode can continue the first field bridge effect transistor as surge protection.

To switch the locking device on and off, is expediently a key switch is provided, its key removable in both switch positions is.

The blocking device increases the DC resistance the telecommunications facility does not. It creates no attenuation or distortion of the incoming and out outgoing dialing impulses and speech signals. Since no mecha African contacts are available, the lock is subject device no wear and causes no Switching noise.  

The locking device only requires the two wires La and Lb of the connecting line to function. It can be connected to these two wires regardless of polarity, with two wires.

The locking device is for everyone in the pulse dialing process ren operated telecommunications equipment ver reversible. It is for main lines and extensions systems suitable. For systems with several consoles len and automatic changeover in the connection can (AWADo) can have a separate one for each station Locking device or a ge for all microphone units common locking device may be provided.

The simple circuit structure of the locking device allows the locking device in the conventional Surface or flush-mounted housings of the junction boxes to accommodate.

In the following the invention is based on one in the Drawing shown embodiment closer explained. Show it

Fig. 1 shows schematically the arrangement of the locking means at the outside line of a telephone device,

Fig. 2 shows the circuit diagram of the locking device and

Fig. 3 a to f diagrams of the loop voltage and the loop current when using the locking device.

Fig. 1 shows a conventional Telefon-Amtsan circuit (eg TAE, VDo, ADo 4 , ADo 8 , ADo 16 or AWADo ) with the wires La and Lb of the connecting line and, if necessary, the wire E, a secondary connection line. A blocking device is connected in parallel to the connections a and b in front of the connection As 1 or the secondary connection NAs 1 of a telephone device. In a connection wire to the locking device, a key switch S 1 is used, which can be actuated by means of a key in two positions. in the neutral position shown, the key switch S 1 is opened and the locking device is out of operation. In the locked position, not shown, the key switch S 1 is closed and the locking device in operation. The key can be removed in both positions.

The locking device is described in detail below with reference to the circuit diagram shown in FIG. 2.

The connected to the connections a and b connecting wires of the locking device lead to a bridge rectifier G 1 , which causes the subsequent circuit of the polarity of the connecting wires to the connections A and B is independent.

The output voltage of the bridge rectifier G 1 is via a resistor R 7 to an existing of the resistors R 2 and R 3 existing voltage divider and another, connected in series with the resistor R 7 resistor R 5 to a first electronic switching element in the form of a Transistor T 2 , which is designed as a MOSFET. A second electronic switching element in the form of a transistor T 1 , also designed as a MOSFET, is connected with its source electrode to the positive output terminal of the bridge rectifier G 1 and its drain electrode is connected to the gate of the transistor T 2 . The gate of transistor T 2 is further connected via an ohmic resistor R 4 to the positive output terminal of the bridge rectifier G 1 and via a capacitor C 1 to the connection point of the resistors R 5 and R 7 . The gate of transistor T 1 is connected to the voltage divider point between the resistors R 2 and R 3 . The gate-source voltages of transistors T 1 and T 2 are each limited to 18 volts by Zener diodes D 1 and D 2, respectively. Before the bridge rectifier G 1 , a varistor R 1 is connected between the connecting wires, which has a breakdown voltage of about 250 volts. A Zener diode D 3 limits the drain-source voltage of transistors T 1 and T 2 to a maximum of approximately 160 volts.

The locking device works in the following way:

In the neutral position of the locking device shown in FIGS . 1 and 2 with the key switch S 1 open, the entire locking device is separated except for the varistor R 1 . The locking device thus has no influence on the connecting line or the telephone device. Incoming call signals, outgoing dialing pulses and incoming and outgoing speech traffic work uninfluenced in a conventional manner, as is explained with the aid of the diagrams of FIGS . 3a, c and e. If the connecting line is not used, for example if the handset of the connected device is hung up, the loop of the device is interrupted. The supply voltage of 60 volts is present at the connections a , b . When the trunk is busy, for example when the handset is removed, the loop in the telephone set is closed. A loop current flows and the voltage at the connections a , b breaks down to about 10 volts. During the voting process, the nsi contact interrupts the loop current in order to generate dialing pulses of approximately 60 ms each. Within these pulses, the voltage at connections a , b rises to the supply voltage of 60 volts. Fig. 3a shows the course of the loop voltage and Fig. 3e the course of the loop current with the handset removed and generation of the dialing pulses. When the handset is placed on the hook, the loop is completely interrupted and the voltage rises again from the value of approximately 10 volts to the supply voltage of 60 volts, as shown in FIG. 3c.

If the key switch S 1 is closed in the locked position, the locking device is connected to the connecting line La, Lb. This works as follows:

If the loop of the telephone equipment is closed when the trunk is busy, for example when the handset is removed, the voltage on the output side of the bridge rectifier G 1 goes from the supply voltage to 60 volts to a voltage which, depending on the line length, is approximately 6 to 17 volts. From the exemplary embodiment shown, 10 volts are specified. This voltage lies across the source-drain path of transistor T 2 and, after recharging capacitor C 1, also at its gate. The gate-source voltage of the transistor T 2 be 0 volts, so that the transistor T 2 blocks. The voltage divider R 2 , R 3 is dimensioned such that the gate-source voltage of the transistor T 1 remains below the threshold value at a voltage which is less than approximately 20 volts, so that the transistor T 1 also blocks. There is therefore no current flowing through the locking device and this does not influence the loop current. The Fig. 3b, d and f are graphs corresponding to Fig. 3a, c and e, when the locking device is in operation the course of the loop voltage and loop current. Since no current flows through the blocking device in the previously described mode of operation when the loop is closed and therefore does not influence the loop voltage and the loop current, the diagrams of FIGS . 3b, d and f in the left area are correct with the diagrams of FIGS . 3a, c and e match.

If an attempt is made to establish a connection while the blocking device is switched on, the nsi contact interrupts the loop of the telephone device for pulse durations of approximately 60 ms during the dialing process. Because of this interruption, the loop voltage rises and since with the voltage on the output side of the bridge rectifier G 1 and the source-drain voltage of the transistor T 2 quickly. The voltage at the gate of transistor T 2 , on the other hand, rises only with a delay with a time constant of about 300 ms, which results from the charging time of the capacitor C 1 via R 4 , D 2 , R 2 and R 3 . The gate-source voltage of transistor T 2 therefore rises, so that transistor T 2 is switched through. The loop current thus flows from the wire La via the bridge rectifier G 1 , the transistor T 2 , the resistors R 5 and R 7 to the wire Lb. The Zener diode D 2 limits the gate-source voltage of the transistor T 2 to 18 volts. The nsi contact closes after about 60 ms before the gate voltage of the transistor T 2 has reached the blocking value. The loop current now flows again via the nsi contact, the voltage of the blocking device drops again to 10 volts and the transistor T 2 blocks again. This process is repeated each time the nsi contact is opened during the dialing process, so that a loop current flows continuously during the dialing process, as shown in the diagram in FIG. 3f and no outgoing dialing pulses can be generated, as can be seen in the diagram in FIG FIG. 3b shows. It is therefore not possible when the locking device is switched on to establish a connection from the locked telephone device.

If the loop of the telephone device is interrupted, for example, by hanging up the handset, the series connection of the capacitor C 1 , the resistor R 4 and the transistor T 2 connected through acts as an integrator. The source-drain voltage of transistor T 2 increases in accordance with the time constant C 1 , R 4 . If this voltage, which is also at the voltage divider R 2 , R 3 , exceeds 20 volts, the transistor T 1 connected in parallel with the resistor R 4 switches through and short-circuits the gate-source path of the transistor T 2 . The transistor T 2 blocks again and the voltage present on the connecting line La, Lb rises again to the supply voltage of 60 volts. This is shown in the diagram of FIG. 3 d.

If, with the loop closed, the telephone device, for example the handset removed, no dialing process is carried out, the gate-source voltage of the transistor T 2 is set to 0 volts after the capacitor C 1 has been charged via the resistor R 4 . The transistor T 2 is selected with a gate-source threshold voltage of approximately 1 volt. Voltage changes below this threshold voltage therefore do not influence the blocking state of the transistor T 2 . The speech signals occurring on incoming calls on the connecting line only cause voltage changes that are clearly below the gate threshold voltage of the transistor T 2 . These speech signals therefore cause no current flow through the transistor T 2 , which could dampen the speech signal. The locking device therefore causes no insertion loss.

In the unoccupied state with an interrupted loop, for example when the handset is on- hook, the supply voltage of 60 volts is on the connecting line La, Lb (or 24 volt for private branch exchanges). This voltage, which is above 20 volts, generates a gate-source voltage of the transistor T 1 via the voltage divider R 2 , R 3 , which turns it on with low resistance. The transistor T 1 connected in parallel with the resistor R 4 short-circuits the gate-source path of the transistor T 2 and keeps it blocked. If an incoming call alternating voltage is superimposed on the supply voltage of 60 volts, the voltage at the gate and source of the transistor T 2 increases simultaneously via the transistor T 1 which is switched through when the amplitude is positive. The Tran sistor T 2 remains blocked. During the negative amplitude of the ringing alternating voltage, the capacitor C 1 holds the voltage at the gate of the transistor T 2 at a value at which the transistor T 2 is still blocking, with a time constant determined by the resistors R 2 , R 3 . The transistor T 2 can therefore not turn on even at the closing voltage rise of the AC voltage. The ringing alternating voltage does not cause any current through the blocking device, so that it is not attenuated and distorted by it.

If, for example, voltage peaks are induced in the connecting lines by lightning discharges or switching operations of adjacent systems, these are derived by the Va ristor R 1 . A residual voltage remaining over the varistor is limited by the limiter diode D 3 to a maximum of 160 volts. The transistors T 1 and T 2 are designed for a drain-source reverse voltage of 200 volts.

Claims (8)

1. On the connecting line of a telecommunications device connectable device for blocking the connection in the pulse dialing method, the incoming call and speech signals passes and blocks outgoing dialing pulses, characterized by the following features:

• a) the loop of the telecommunications device is bridged by a first controllable electronic switching element;
• b) the first switching element blocks when its control input is present on the loop voltage present at the connecting line;
• c) the pending loop voltage is present at the control input of the switching element via a delay element which delays the rise in voltage at the control input by a period of time which is longer than the duration of the dialing pulses;
• d) the delay element is bridged by a second controllable electronic switching element which can be controlled by the loop voltage applied to the connecting line and is switched through when this loop voltage assumes the value of the full supply voltage when the loop is interrupted.

2. Locking device according to claim 1, characterized in that the first switching element is a switching transistor ( T 2 ) and the second switching element is a switching transistor ( T 1 ), preferably each a MOS field effect transistor. 3. Locking device according to claim 1 or 2, characterized in that it is connected via a bridge rectifier ( G 1 ) to the wires of the connecting line ( La, Lb ). 4. Locking device according to claim 2, characterized in that the delay element is an RC delay element ( C 1 , R 4 , R 2 , R 3 ). 5. Locking device according to claims 2 and 4, characterized in that the second switching transistor ( T 1 ) bridges the gate-source path of the first switching transistor ( T 2 ) and that at the gate of the second switching transistor ( T 1 ) the loop voltage applied to the connecting line is applied via a voltage divider ( R 2 , R 3 ), the voltage divider ( R 2 , R 3 ) being dimensioned such that the switching transistor ( T 1 ) switches through when the loop voltage assumes the value of the full supply voltage. 6. Locking device on one of the preceding claims, characterized in that a varistor ( R 1 ) is used as overvoltage protection between the connections to the locking device. 7. Locking device according to claim 6, characterized in that a voltage limiter diode ( D 3 ) is connected in parallel to the first switching element. 8. Locking device according to one of the preceding claims, characterized in that a key switch ( S 1 ) is provided in the connection of the locking device with the connecting line.