DE4008885C1 - Telephone subscriber's installation with plug-in extensions - has timed circuits in sockets holding connection so that plug can be removed and inserted in other socket - Google Patents

Abstract

The subscriber's installation possesses at least two socket connections in series for at most one telephone jack each, the jacks separating the two sockets. A holding circuit connected to the free terminals (a2,b2) of the last socket in the series (B) takes over the loop current for an interval given by a time control when the exchange lines (La,Lb) are switched through, reproducing the d.c. and a.c. resistances of telephone equipment and interrupting the loop current after the expiry of this interval. ADVANTAGE - Telephone jack can be taken from one socket and placed in another without breaking connection.

Description

The invention relates to a telecommunications connection unit (TAE system) according to the generic term of the Claim 1.

TAE systems of this type have several junction boxes Connection sockets to which only one telephone set at the same time a telephone connector can be connected. The sockets have contacts, which are the connecting lines from one socket to the next in a row switch. If a telephone connector is plugged into one of the Plugged in sockets, so these contacts separated and the connecting sockets connected in series are disconnected from the connecting cables. The in line last connection socket is at your free continuing Line connections not used. Is in the entire TAE  System in no connection socket a telephone connector plugged in, the connecting cables are open up to this Termination of the last socket switched through.

Becomes the only approved phone during a phone call Pull the appliance plug out of the connection socket, so the official lines through to the open termination of the last socket switches. This will make the telephone connection instantly interrupted because the loop current is no longer over the open connection lines can flow.

The invention has for its object a TAE system to create the genus mentioned at the beginning, in which it is possible to remove the telephone plug during a to pull the existing connection from the connection socket currently in use and preferably in another connector stuck without interrupting the connection.

This task is carried out in a TAE system of the type mentioned at the beginning Genus according to the invention solved by the features of Claim 1.

Advantageous embodiments of the invention are in the Subclaims specified.

In the TAE system according to the invention it is possible to an existing connection the telephone connector to pull and into the connector socket of another connector  socket without interrupting the connection, to make the phone call z. B. in another room put. This is the last in the row of the TAE system Connection socket on their free line connections, from to whom the connecting line is no longer operated, a bracket connected to a telephone for the loop current. Will during a existing connection of the telephone connector is pulled, so the hold circuit takes over the loop current and maintains the connection until the only usable telephone set the plug is plugged back into one of the connection sockets becomes.

To avoid that the loop of the TAE system over the Hold circuit is constantly closed when in none of the A telephone connector is plugged in, the hold circuit has a control which at Pulling the only telephone connector provided during one existing connection is started and the replica of the Telephone sets for a predetermined period of time, e.g. B. Maintained for 60 to 90 seconds. After a period of time the time control interrupts the loop current, by making the connection of the line connections high-resistance switches.

The timing control preferably has a Schmitt trigger on that triggered when the trunk lines were switched through and thereby switches for direct current and alternating current Resistor branches actuated. After one through an RC link The Schmitt trigger flips back into the specified time period its idle state and blocks the DC and AC current resistance branches, so that the connection of the line connections of the connection socket via the holding circuit high becomes ohmic.  

A voltage monitor ensures that the holding circuit does not respond to interference pulses or call signals if the operating voltage of the exchange line on the holding circuit is present.

The hold circuit is powered by the outside line. Around the hold circuit regardless of the polarity of the trunk lines to do is in the input of the hold circuit Bridge rectifier provided.

There is also lightning protection in the input of the hold circuit facility provided.

The following is an example of the invention explained in more detail using the attached circuit diagram.

To the last connection socket B of a TAE system with a plurality of connection sockets connected in series, on the one hand the line wires of the trunk lines La and Lb coming from the upstream connection sockets and the call signal line W are connected. The holding circuit described below is connected to the free line connections a 2 and b 2 which are no longer connected. Contacts of the connection socket connect the trunk lines La and Lb to the line connections a 2 and b 2 , respectively, if no telephone connector is inserted into the connection socket B. If a telephone connector is inserted, it disconnects the contacts so that the line connections a 2 and b 2 are free.

The line connections a 2 and b 2 are bridged by a varistor R 1 , which serves as a lightning protection device for the holding circuit. The varistor R 1 is designed so that with a pulse current of 50 A, the voltage applied to the holding circuit does not rise above 300 V. The response voltage of the varistor R 1 is chosen so high that the insulation resistance is maintained at the maximum operating voltage and that no interference from leakage currents occur when the call signal is present. The switching transistors T 2 , T 3 and T 7 of the holding circuit are designed in their operating voltage so that interference pulses up to max. 300 V will not lead to a functional failure.

Furthermore, a bridge rectifier consisting of diodes D 1 , D 2 , D 3 and D 4 is connected to line connections a 2 and b 2 . This bridge rectifier D 1 to D 4 makes the subsequent hold circuit independent of the polarity of the exchange lines La and Lb.

The holding circuit connected to the output of the bridge rectifier D 1 to D 4 has a direct current resistance branch and an alternating current resistance branch. The DC resistance branch consists of a series connection connected to the output connections of the bridge rectifier D 1 to D 4 from an ohmic resistor R 12 , a transistor T 6 , an ohmic resistor R 7 , a transistor T 3 and an ohm ' resistance R 15 . The transistor T 3 acts as a switch for the direct current resistance branch.

The AC resistance branch consists of a series circuit connected to the output connections of the bridge rectifier D 1 to D 4 , comprising a capacitor C 5 connected in parallel with an ohmic resistor R 18 , a transistor T 7 and an ohmic resistor R 19 . The Tran sistor T 7 serves as a switch of the AC resistance stand branch. This AC resistance branch is preceded in series by a series connection of three diodes D 8 , D 9 and D 10 which are polarized in the forward direction.

The hold circuit also has a time control. The time control contains a Schmitt trigger with transistors T 5 and T 6 on the one hand and a transistor T 4 on the other. The transistors T 4 and T 6 are emitter-coupled. The voltage drop across the diodes D 8 to D 10 is applied to the Schmitt trigger as the operating voltage. The base of the transistor T 5 , the emitter of which controls the transistor T 6 via its base, lies on an electrolytic capacitor C 3 of large capacity and an ohmic resistance R 9 with an ohmic series resistor R 11 on the via the diodes D 8 to D 10 falling voltage. The resistor R 9 is bridged by a diode D 7 connected in parallel. The base of transistor T 4 lies on a voltage conductor formed by resistors R 12 , R 10 and R 8 .

The Schmitt trigger controls a transistor T 2 . The transistor T 2 serves as a switch and supplies the base current for switching the transistor T 3 on the one hand via a voltage conductor from the resistors R 13 and R 14 and on the other hand via a series resistor R 16 the base current for switching the transistor T 7 .

Finally, the hold circuit also has a voltage monitor. The voltage monitor contains a MOSFET T 1 , which is connected between the collector of the transistor T 2 and the ground pole of the bridge rectifier D 1 to D 4 . The gate of the MOSFET T 1 is connected via a voltage divider consisting of an ohmic resistor R 2 , a Zener diode D 6 and an ohmic resistor R 3 to the operating voltage of the circuit at the connections of the bridge rectifier D 1 to D 4 . In parallel with the resistor R 3 , a capacitor C 1 is connected to the gate-source path of the MOSFET T 1 .

The holding circuit described according to the attached Circuit diagram works in the following way:

If the line connections a 2 and b 2 of the connection socket B are free because the connection to the exchange lines La and Lb is interrupted by a telephone plug inserted into any of the connection sockets connected in series, the transistors T 1 to T 6 are blocked.

If the telephone set plug is pulled from the respective connection socket during an existing call, the exchange lines La and Lb are connected to the line connections a 2 and b 2 with the loop current. As a result (because of the bridge rectifier D 1 to D 4 regardless of the polarity of the exchange lines La and Lb), a voltage pulse is applied to the base of the transistor T 7 via the diode D 8 to D 10 , the capacitor C 4 and the resistor R 17 . A current pulse flows through the transistor T 7 . During this current pulse through transistor T 7 , transistor T 2 receives a negative base voltage via resistors R 6 , R 7 , R 18 and transistor T 7 and is switched through. As a result, a positive base voltage is applied to the transistors T 3 and T 7 and these transistors become conductive in order to switch on the DC resistance branch and the AC resistance branch.

If transistor T 7 becomes conductive as a result of the start pulse, then a voltage of approx. 2.3 V drops across diodes D 8 to D 10, which voltage is applied to the Schmitt trigger. The capacitor C 3 transfers this voltage via the resistor R 11 to the base of the transistor T 5 , which thereby turns on the transistor T 6 . The transistor T 4 remains blocked via the voltage divider R 10 , R 8 . As a result, the transistor T 2 is kept switched through via the voltage divider R 5 , R 6 , R 7 , T 3 and R 15 and continues to supply the base current for the transistors T 3 and T 7 , which keep the DC resistance branch and the impedance branch switched on .

The capacitor C 3 now slowly charges via the resistor R 9 and the series circuit comprising the resistor R 11 and the base sections of the transistors T 5 and T 6 to a voltage of approximately 0.9 V. This is achieved after a given period of time of approximately 60 to 90 seconds, determined by the capacitance of the capacitor C 3 and the resistances mentioned. If the capacitor C 3 is charged to such an extent, the remaining base voltage at the transistors T 5 and T 6 is no longer sufficient to control them. Due to the emitter coupling and the changing voltage conditions at the voltage divider R 12 , R 10 and R 8 , the transistor T 4 turns on, while the transistors T 5 and T 6 block. The switched transistor T 4 short-circuits the base-emitter path of the transistor T 2 , so that it blocks. By blocking the transistor T 2 , this also switches off the transistor T 7 and, with a delay, the transistor T 3 . By blocking the transistors T 3 and T 7 , the loop current through the line connections a 2 and b 2 is interrupted and the voltage supply to the Schmitt trigger via the voltage drop across the diodes D 8 to D 10 is switched off.

The capacitor C 3 then discharges again via the diode D 7 and the parallel series connections of the resistors R 6 , R 5 , R 4 and R 7 , R 8 , R 10 , R 12 except for the residual voltage of the diode D 7 . The further complete discharge of the capacitor C 3 takes place via R 9 . As a result, the entire holding circuit has reached its initial state again, but it is at the operating voltage of the exchange lines until it is switched off again by plugging a telephone set in one of the connection sockets.

During the hold time, the DC resistance branch is closed and switched on via the conductive transistor T 3 . The transistor R 3 is, as described above, controlled by the transistor T 2 via the voltage divider R 13 and R 14 . The base-emitter path of transistor T 3 is additionally bridged by a capacitor C 2 , which derives low-frequency voltages to ground. The dimensioning of the resistors R 13 and R 14 and the negative feedback through the resistor R 15 are chosen so that the transistor T 3 does not work in the saturation range. The screening out of low-frequency components by the capacitor C 2 at the base of T 3 results in a high impedance in the low-frequency transmission range of 300-3400 Hz. The DC resistance of the DC resistance branch results essentially from the resistor R 12 , the transistor T 6 , the opponent was R 7 , the transistor T 3 and the resistor R 15 . This DC resistance is around 500 ohms. Due to the parallel to this DC resistance branch series connection of the resistor R 18 , the transistor T 7 and the resistor R 19 results in taking into account the voltage drop across the diodes D 8 to D 10, a DC resistance of the entire holding circuit was from about 320 to 450 Ohm. This DC resistance of the entire holding circuit simulates the DC resistance of the telephone set.

In order to meet the value of the return loss required for the telephone network, there is a stable and accurate after formation of the telephone impedance Z _R. For this purpose, the DC resistance branch and the AC resistance branch are separated via the separate switches by the transistors T 3 and T 7 . The AC branch is turned on by transistor T 7 . This transistor T 7 is turned on again in the manner described above during the holding time by the transistor T 2 . The impedance of the alternating current branch from the resistor R 18 , the capacitor C 5 , the transistor T 7 and the resistor R 19 essentially determines the impedance of the entire holding circuit, which simulates the telephone impedance Z _R.

As soon as the holding time of approx. 60 to 90 seconds has expired and the loop current through the holding circuit is interrupted by the transistors T 3 and T 7 , the operating voltage of the exchange lines La, Lb is from 24 to 60 V above the holding circuit, until one is inserted Telefonappa ratesteckers in one of the sockets, the line connections a 2 and b 2 are separated again. So that the hold circuit does not respond to interference pulses or pending call signals in this state, the voltage monitoring is provided.

The voltage monitor contains in particular the MOSFET T 1 , which prevents the holding circuit from starting at a voltage above 23 volts. The operating voltage applied to the holding circuit lies across the voltage divider R 2 , D 6 and R 3 at the gate of the MOSFET T 1 . If the holding circuit is voltage-free because a telephone connector is plugged into one of the connection sockets, the MOSFET T 1 is blocked. If the operating voltage rises above 23 V through the existing exchange lines, the gate-source voltage connected across the voltage divider across the resistor R 3 switches the MOSFET T 1 through. The MOSFET T 1 thereby sets the base of the transistors T 3 and T 7 to ground, so that they block and the latch circuit does not respond. The start pulse is derived via diode D 11 and MOSFET T 1 to ground.

The capacitor C 1 present at the gate of the MOSFET T 1 delays the switching on of T 1 , thereby ensuring a safe switching on of the holding circuit and trouble-free operation with the charge pulses at a high level. A Zener diode D 5 protects the MOSFET T 1 from damage caused by excessive gate-source voltage in the event of interference pulses.

Claims (9)

1. Telecommunication connection unit system (TAE system) with at least two through-connected connection sockets for simultaneous insertion of at most one telephone set, whereby the telephone sockets connected in a connection socket are separated by the connection sockets connected in series, characterized by one to the free ones Line connections (a 2 , b 2 ) of the last connection socket (B) connected to the holding circuit, which takes over the loop current when switching through the exchange lines (La, Lb) for a period of time predetermined by a time control, thereby the DC resistance and the AC resistance simulates a telephone set and interrupts the loop current after this period. 2. TAE system according to claim 1, characterized in that the hold circuit is powered by the outside line. 3. TAE system according to claim 1 or 2, characterized in that the time control has a Schmitt trigger (T 5 , T 6 , T 4 ) and an electronic switch (T 2 ) controlled by the Schmitt trigger, the pre given duration is determined by an RC element controlling the Schmitt trigger (C 3 , R 9 , R 11 , T 5 , T 6 ). 4. TAE system according to one of the preceding claims, characterized in that the time control (Schmitt trigger, electronic switch T 2 ) electronic switch African a DC resistance branch (T 3 ) and an AC resistance branch (T 7 ) for the predetermined Time period switches on. 5. TAE system according to claim 4, characterized in that the DC resistance branch has an electronic switch (T 3 ) containing series connection of ohmic resistors (R 12 , T 6 , R 7 , R 15 ). 6. TAE system according to Claim 4, characterized in that the AC resistance branch has an RC element (R 18 , C 5 ) connected in series with the electronic switch (T 7 ). 7. TAE system according to one of the preceding claims, characterized in that a voltage monitoring is provided which has an electronic switch (T 1 ), the electronic switch (T 3 , T 7 ) of the DC resistance branch and the AC resistance branch keeps switched off if, after the specified period of time has elapsed, the operating voltage applied to the holding circuit exceeds a specified value. 8. TAE system according to one of the preceding claims, characterized in that the holding circuit via a bridge rectifier (D 1 to D 4 ) at the line connections (a 2 , b 2 ) of the connection socket (B). 9. TAE system according to one of the preceding claims, characterized in that the holding circuit has a bridging the line connections (a 2 , b 2 ) varistor (R 1 ) as lightning protection.