HU196539B - Line-party-line circuit to telecommunication central exchanges - Google Patents

Abstract

The present invention relates to a solo-twin line current for telephone exchanges having a line-to-pair connection and 5 connections to two central pairs. The core of the line current according to the invention is that there are two units of the same design (10, 50), one of the lines (A) of one line (10) on one line (A) of the line pair and another branch of the other unit (50). (b1) is connected, the other line (B) of the line pair is connected to one of the other branches (b) of one unit (10) and one branch (a ') of the other unit (50), the central side being one unit (10) branch (a and b) are connected to two connections (Ai and Bi) of one central pair, two branches of the other unit (50) (a 'and kills the two connections of the other central pair (A and 20Bz) on the units (10) , 50) in one of the branches (a, aO current switch (11, 51) in the other branches (b, b) is equipped with a rest current switch (12, 52), a pair of 25 optocouplers (13; 53), the output of the optocoupler (13, 53) is connected to the input of the control circuit (17, 57) and each the output of the control circuit (17, 57) is connected to the actuator input of the working circuit 196539 (11 or 51) of the own unit (10 or 50) and the rest current switch (52 and 12) of the other unit (50 and 10). -1-

Description

FIELD OF THE INVENTION The present invention relates to a single-twin line current for telephone exchanges having a line-pair connection and two central-pair connection.

It is known that twin subscriber stations are used in the telephone subscriber network in order to make better use of telephone lines. On twin subscriber lines, two subscribers can be connected to the telecommunication center on a single pair of wires, the selective separation of which is provided by the special circuits used in the center circuit and the subscriber side.

Most telephone exchanges already have what is known as a twin subscriber line, but there are also centers that are only capable of connecting single subscribers. In such cases, the telephone company or post office may also consider it necessary to switch on twin lines. In order to convert a clear-line subscriber line into a twin-line, it is necessary to include a single-twin line stream.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a single-to-twin line circuit that can be used in telecommunication exchanges that do not have twin subscriber line assemblies, i.e., telecommunication exchanges that are exclusively capable of interconnecting solo subscriber stations.

Telecommunication centers are understood to be primarily telephone exchanges, but also include centers which transmit other information, such as telex or other data.

The object of the present invention has been achieved by the introduction of the single-twin-current disease described in the introduction by having two units of the same design, one of which is the branch of the line pair A and the b 'branch of the other unit. Line B is joined by branch b of one unit and branch a 'of another unit, one unit a and b on the central side to connect Al and Bl of one central pair, and branch A and b of the other unit A2 and B2, within the units, a power switch for branches a and 'a, a dormant switch for branches b and b', an optocoupler input in series with the dc switch, an output of the optocoupler connected to a control circuit input, and the on-mode switch on your own unit and the on-off switch on the other unit is connected to the actuator input.

The sol-twin lineage disease according to the invention has several advantages. One advantage is that it can be connected to any telecommunication exchange that does not have its own twin subscriber line assembly. A further advantage is that it consists of two units of exactly the same construction, which makes manufacturing simpler and less expensive. Another advantage is that the structure of the circuit is electronic, so there is no need to worry about aging and wear of moving parts. The circuit contains very few components and requires little space.

In a preferred embodiment of the invention, a delay circuit is inserted between the output of the optocoupler and the control circuit. The advantage of using a delay circuit is that short-term interfering signals, which can be received from both the line and the control panel, do not interfere with the control circuit, and thus the operation of the switches is not insecure.

According to a further preferred embodiment, the output of the optocoupler is connected to the control input of a restartable monostable tilt lever and its output is connected to the input of the control circuit. The use of the restartable monostable tilt when the dialing station is selected by dialing the line current is convenient, since the restartable monostable tilt ensures that the control circuit functions, even when the pulses are pulsed, by closing or disconnecting the corresponding switches.

In order to prevent distortion of the telecommunication line by the light emitting diode commonly used in the optocouplers on its inlet side, a diode is connected from the outside parallel to it.

Preferably, a series of diodes, mimicking the input characteristics of the optocoupler, are inserted in each of the units, respectively. This ensures perfect symmetry between branches a and b and 'and b. Preferably, these serial diodes have a further diode connected in parallel, which has the same role as the diode connected in parallel with the optocoupler input as described above.

In one embodiment, the switches comprise relays. This is needed when regulations for control panels require mechanical breakdown of switches. Unless specified, switches are preferably semiconductor switches. The latter case has the advantage that the solo-twin circuit circuit according to the invention does not contain any moving component.

Preferably, an amplifier is provided at the output of the optocoupler.

The solo twin circuit of the present invention will now be described in more detail in connection with an exemplary embodiment. In the drawings it is

Figure 1 illustrates the connection of a solo-twin line circuit according to the invention to a twin subscriber system or a solo telecommunications center,

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Figure 2 illustrates the internal structure of a solo-twin circuit according to the invention in a block diagram, and

Figure 3 illustrates a possible circuit arrangement for a single-twin loop circuit.

As shown in Fig. 1, the solo twin of the present invention is located at or near the telecommunication exchange at the telecommunication center, and the Ai, Bi and A2, Βς connections are connected to a single subscriber connection at the exchange. In line current 1, it is separated from the center by DC capacitors 4 and 5, and receives line currents through conventional power bridges 2 and 3.

On the subscriber side of line 1, it is connected to lines A and B of a single pair of wires of subscriber line 6. Line 6 is connected to subscribers 8 and 9 via a twin assembly 7 in a known manner. The line circuit 1 according to the invention connects the Ai ', Bi' connections of the subscriber 8 via the twin assembly 7 to the central Ai, Bi connections, or the A2 ', Bz' connections of the subscriber 9 to the central A2, B2 connections.

The internal structure of the line stream 1 according to the invention is shown in Figure 2. The line circuit 1 comprises two 10-ohm 50 units of identical design. In the following, only the unit 10 will be described in more detail in the wiring arrangement, and parts identical to the parts indicated therein will be designated by a reference numeral greater than 40 in unit 50.

In unit 10, line A is connected to the center-side connection Ai through the branch, while line B is connected to connection Bi through the branch O. There are switches 11 and 12 in branches a and b, of which switch 11 is in the idle state, i.e., when neither of the subscriber loops is closed, the loop current is not flowing, there is no connection, it is disconnected and at the same time. switch is closed. An optocoupler 13 is inserted in series with switch 12 in series b with its input. The inlet side of the optocoupler 13 is generally comprised of a light emitting diode, while the output side has an emitter collector section of a phototransistor. A resistor 15 is preferably connected to the emitter circuit of the phototransistor, while its collector is connected to a control circuit 17 via an amplifying transistor 16 and a delay circuit 18. The output of this control circuit 17 is connected to the actuator input of the switch 11, but is also connected to the actuator input 52 of the other unit 50 in the circuit circuit 1 when closed.

The collector of amplifier transistor 16 is also connected to a start-up input of a monostable tilt 19 via a circuit consisting of a separation diode 20 and a counter-position 21. The monostable tilt circuit 19 is a re-trigger monostable tilt loop whose output is also connected to the control circuit 17.

With the light emitting diode at the input of the optocoupler 13, a diode 14 is connected externally in parallel.

In order for the line circuit 1 to be symmetrical in relation to its external connection points in branches a and b, two series-connected diodes 22 and 23 mimicking the light emitting diode are connected in series to the switch 11. In parallel to these two diodes 22 and 23, diode 24 corresponding to diode 14 is connected.

As the output of the control circuit 17 is connected to the actuator input of the switch 52 of the unit 50, the output of the control circuit 57 in the unit 50 is coupled to the actuator input of the switch 12 in 10. The output of the control circuit 17 is also whereas the output of the control current 57 provides the busy current Ci to the line current associated with unit 10.

The unit 10 has panel-side Ai and Bi connections that are connected to the individual subscriber connections of the telecommunication center. Similarly, the central connections A2, B2 of the unit 50 are connected to a further single subscriber connection of the telecommunication center. On the subscriber side, the terminals of the units 10 and 50 form the parallel lines A and B; that is, branch a of unit 10 is connected to branch b 'of unit 50, and branch b of unit 10 is connected to branch a' of unit 50.

The switches 11, 12 and 51, 52 may be semiconductor switches or electromechanical relays. With a semiconductor switch there is no wear component, while with an electromechanical relay a better galvanic separation can be achieved.

The operation of the line current 1 according to the invention, shown in Figure 2 and described above, is as follows:

When idle, that is, when neither subscriber 8 or 9 (FIG. 1) makes a call or any of the subscribers 8 or 9, switch 11 in open state 10, switch 51 in open state 50 also interrupts the path of the line stream. If, for example, subscriber 8 makes a call and lifts his handset, ground is connected to line B via twin assembly 7, and unit 10 closes the circuit through optocoupler 13, closed switch 12 and power supply 2, and it will flow. Given that the β 'branch in unit 50-37 is connected to line B, no current can flow due to the open state of the switch. Current on branch b causes a signal at the output of the optocoupler 13 to be applied to the control circuit 17 via the delay circuit 18 mounted on the transistor 16. The output of the control circuit 17 then closes the switch 11, disconnects the switch 52 in unit 50, and provides a busy signal to the central solo line of the telecommunication unit of unit 50 via the busy output C1.

When the switch 11 closes, the Ai, Bi connections are connected to the Ai ¹ , Bi 'connections of the subscriber 8, while the opening of the switch 52 in unit 50 disconnects the A 1, Bz connections from the A and B lines.

The delay time of the delay circuit 18 is only a few msec and serves to prevent any transient current surges on the b branch from acting on the control circuit 17.

When dialing, my pulse pulses tear the line current. In order to prevent this interruption from actuating the switches 11, 52 via the control circuit 17, the resetable monostable tilt loop 19 is pulsed by the pulses and provides continuous control of the control circuit 17 during the pulses. Thus, the switches 11 and 52 are prevented from operating at the pulse rate. Consequently, the first requirement is that the tilting time of the monostable tilt 19 is longer than the duration of the pulse pulses.

After dialing, the line current flows through the a and tree branches of unit 10 until the subscriber 8 hangs up.

If the subscriber 9 is the originator of the call, it is connected to line branch A, whereupon the branch b 'in unit 50 flows from the power bridge 3 via the optocoupler 53 and the closed switch. In this case, the unit 10 disconnects the connections Ai, Bi from the line branches A, B, and the unit 50 connects the subscriber 9 to the connections A2, Bz of the exchange. The operation of the unit 50 is the same as that of the unit 10 described above.

If subscriber 8 or 9 is not the originator but one, such as subscriber 8, is called from the telecommunication center at connection Bi, branch b, optocoupler light emitting diode 13, line B and twin assembly and 8 subscriber ringing circuits flow to the ground. The bell current at the control panels is an AC voltage superimposed on the mains DC voltage (48 V) that is higher than the mains DC voltage. This means that the ring current is alternating current flowing through the light emitting diode of the optocoupler 13 at one current direction and through the diode 14 at the other current direction. Through the optocoupler 13, the ring current also actuates the control circuit 17 and the switches 11 and 52 connected to its output in the same way as described above. In the other current direction, the current flowing through the optocoupler 13 is interrupted, whereupon the monostable tilt arm 19 tumbles and continues to operate the control circuit 17.

The ringing current is a periodically intermittent alternating current. It is desirable for the switch 11 to remain closed during breaks in the ringing period and for the switch 52 to remain open at the same time. Therefore, another requirement for the monostable tilt circuit 19 is that its tilt time is longer than the pause time between the two ringing periods. Given that the ringing period is longer than the period of the pulse pulses already detailed above, the monostable tilt circuit 19 must meet the condition defined by the ringing periods.

Fig. 3 shows a unit 10 of the line current 1 shown in Fig. 2, which shows a possible embodiment of the control circuit 17, the delay circuit 18 and the monostable tilt 19. In this case, switches 11, 12, 51, and 52 are formed by relay contacts such that relay 46 actuates switches 11 and 52, while relay 86 in unit 50 actuates switches 12, 51.

The relay 46 is inserted in the collector circuit 45 of the transistor 45, which forms the control circuit 17, which is protected from voltage surges by a diode 47 connected in parallel with the relay 46. The inputs of the control circuit 17 are led through diodes 41 and 42 to the base of transistor 45 to which a base resistor 44 is coupled. The diodes 41 and 42 provide separation between the output of the delay circuit 18 and the output of the monostable tilt 19.

The delay circuit 18 is comprised of an RC member consisting of a series resistor 40 and a ground capacitor 43 connected to a collector of transistor 16. The transistor 16 receives the supply voltage through a resistor 39.

The restartable monostable tilt circuit 19 comprises a circuit formed of transistors 25 and 31. Connected to the base of the transistor 25 is a diode 20 passing through a series resistor 30, which determines the base point of the transducer and the biasing of the didode 20 by the resistor 21 coupled to the base and the emitter. Connected to the collector circuit resistor 26 of transistor 25 is a RC member consisting of a series capacitor 27 and a parallel resistor 28 whose output is connected to the base of transistor 31. A transistor diode 32 is connected in series to the emitter circuit of the transistor 31, while its collector has a resistor 33. The time constant of the monostable tilt loop constructed in this way is determined by the input resistance of the capacitor 27, the resistor 28 and the base transistor of the transistor 31, respectively.

In the illustrated embodiment, the collector 31 of the transistor 31 forming the output of the monostable tilt 19 is connected via a series resistor 34 to an inverter stage formed by the transistor 36. A resistor 35 is connected between the base emitter of the transistor 36 and the resistor 37 is formed by the working resistance of its collector. The collector of transistor 36 forms the output of the inverter stage, which is connected via a serial resistor 38 to the diode 42 constituting the input 20 of the control circuit 17.

In Figure 3, unit 50 is not detailed for clarity; although the same construction as described in detail above 10 converting unit ²⁵ off.

The circuit arrangement shown in Figure 3 is only one possible embodiment.

The circuit may be constructed with a number of other equivalent units so that the monostable tilt 19 can be implemented with an integrated circuit. It is also possible to design both units 10 and 50 as integrated circuits or hybrid circuits.

Claims (9)

A single-twin line stream for telephone exchanges having a line pair connection and two center pair connection, characterized in that it has two units (10, 50) of the same configuration, one line branch (A) of the line pair one branch (a) of one unit (10) and the other branch (b) of the other unit (50) are connected, the other branch (b) of one unit (10) and the other unit (50) one branch (a ¹ ) is connected, on the central side two branches (a and b) of one unit (10) for two joints (Ai and Bi) of one central pair, and two branches (a 'and b *) of the other unit (50) ) is connected to the two connections (A1 and B2) of the other central pair, within the units (10, 50), one of the branches (a, a *) has a runaway switch (11, 51) and the other branches (b, b ¹ ) a switch (12, 52) is provided, the dc switch (12, 52) is in series optocoupler (1) Input 3, 53) is provided, the output of the optocoupler (13, 53) is connected to the input of a control circuit (17, 57), and the output of each control circuit (17, 57) is a power switch (11 and 51, respectively) of its own unit. ) and to the actuator input of the other unit's (50 and 10) dc switches (52 and 12, respectively). Line current according to claim 1, characterized in that a delay circuit (18, 58) is inserted between the output of the optocoupler (13, 53) and the control circuit (17, 57). 3. From the line current according to claim 1 or 2, characterized in that the control input of a resettable monostable tilt lever (19, 59) is connected to the output of the optocoupler (13, 53) and connected to an input of the control circuit (17, 57). . 4. A line current according to any one of claims 1 to 5, characterized in that a diode (14, 54) is coupled to the input side of the optocoupler (13, 53) by a light emitting diode in the optocoupler (13, 53). 5. A line current according to any one of claims 1 to 4, characterized in that one of the branches (a and aO) is fitted with serial diodes (22, 23 and 62, 63) mimicking the input characteristics of the optocoupler (13, 53). Line current according to claim 5, characterized in that an additional diode (24, 54) is connected in parallel with the serial diodes (22, 23 and 62, 63). 7. Line current according to any one of claims 1 to 3, characterized in that the switches (11, 12, 51, 52) are formed by relays (46, 86). 8. A line current according to any one of claims 1 to 4, characterized in that the switches (11, 12, 51, 52) are semiconductor switches. 9. Line current according to any one of claims 1 to 3, characterized in that an amplifier is provided at the output of the optocoupler (13, 53).