HU193107B - Circuit arrangement for making circuit of main route, in particular to digital sub-exchanges - Google Patents

Abstract

A trunk circuit comprises a dialled digit sensing transistor 2 controlled with optical coupling, CS1, a muting relay A, optical coupling CS2 connected to the coil of the muting relay and a dial pulse control circuit 6. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for implementing a trunk circuit of telephone exchanges, which is capable of connecting both small and large number of PBXs to trunk lines.

The circuit layout is particularly suited for integrating digital PBXs in an analog environment.

Various solutions of the mainline circuits of the PBXs are known from the domestic and foreign literature, from the manuals of various equipment purchased abroad. These solutions generally share the same basic objectives, but may also address specific sub-tasks, depending on the application.

Such a known trunk circuit is shown

l. which is used in QA type electronic PBXs. A feature of this is that ring reception, loop closing and dial pulse output, as well as input of dial tones are solved with relays. Its basic feature is that the line is closed with a DC solenoid, which can be connected to a transformer design if necessary.

The trunk circuit shall provide DC connection of the main switching circuit when the DC loop is established.

It should be capable of loop breaking, with low impedance during the pulse output of the dials. The circuit must detect a ring from the main control panel by means of a ring receiving circuit. This ring receiving circuit typically has two types. One type is the low impedance version, which can be switched off from the audio line. The other type is the AC impedance, DC break, which is typically a transformer circuit.

The trunk circuit shall ensure that the line is sealed in the speech band and in the frequency range used. The circuit must protect the equipment from transient overvoltages on the connection line. The trunk circuit is generally capable of detecting the polarity of the DC loop fed from the exchange and sends information to the controller when the loop is reversed. In order to measure and record the number of city calls, they also have a charging circuit and can be supplemented with trunk circuits. The digital switching field is quad-wire by nature, so if the PBX is operating in an analog environment, a hybrid circuit is needed to accomplish the 2/4 wire conversion. This circuit is in practice a transformer solution (several versions), but it can also be solved with an electronic 2/4 wire converter. A very important part of the hybrid circuit is a properly designed and variable line imitation. The functions listed here are generally implemented in accordance with the design of the main circuitry of the entire sub-center, in accordance with the state of the art of the electronic circuitry in the equipment. One of the typical components of these circuits is the pre-magnetized choke, which is intended to pass the DC power of the main control panel, but must be open in terms of sound frequency. This task can only be accomplished with a large component, which is not allowed in digital centers. A trunk line assembly with a 2/4 wire converter, the use of a pre-magnetized hybrid circuit is known in prescriptions. Here, a circuit element performs two electrical functions, DC termination and 2/4 wire conversion. Here, too, a large transformer must be used for the required electrical parameters, and a fairly heavy-duty relay must be used to realize the disc short circuit during dialing. If the contact of the dialer circuit is not of electronic design, the circuit requires another large component, a pulse relay. In addition to the size of this solution, it is not practical to use in digital PBXs due to interference pulses during operation. The traditional low impedance solution of the ring receiving circuit requires sub-speech isolation, which is not expedient in size and power. The high impedance ring receiver, which is permanently on the frequency line in transformer design, in tuned or non-tuned design. The solution used has good electrical properties, but the implementation of the transformer is expensive compared to this task.

Summarizing the requirements for the trunking circuits, considering the shortcomings of the implemented circuits, for use in ^this digital PBX, the following objectives have been set for the design of a new type of trunking assembly. Replacing a large pre-magnetized choke or pre-magnetized hybrid with a small electronic circuit with no pre-magnetized hybrid. Replacement of High Impedance Transformer Ring Receiver Transformer with Electronic Components. Integrated circuit pulse generation with electronic dialing.

Our aim is to provide a switching arrangement suitable for connecting analogue switches to digital switches where the outgoing city call to the main switch is automatic, the incoming city call being handed over.

The present invention is based on the discovery that a commercially available control circuit used in telephone extension devices, telephone exchange PBXs and

-2193107 also as a pulse control pulse control circuit.

It has been our object to provide a circuit arrangement for creating a mainline circuitry for telephone PBXs that includes a tariff receiving circuit, a high impedance blockable ring receiving circuit (with electronic components), an overvoltage varistor, a loop polarity monitoring loop, and dial short circuit control circuit, characterized in that the ring receiver includes a high sensitivity optical coupler, the loop polarity monitoring circuit includes an optical coupler, the controlled current consumer is symmetrical, the loop and disk short circuit - the control pulse control circuit, is connected to a power supply, another control output is connected to an interface circuit, which interface circuit outputs are connected to the controlled power supply, and which interface circuit is connected to the ringing receiver via an optical coupler.

BRIEF DESCRIPTION OF THE DRAWINGS The subject matter of the invention will now be described in more detail by means of figures.

Figure 1 shows a trunk circuit of prior art QA electronic PBXs.

Figure 2 shows an embodiment of the circuit arrangement according to the invention.

The known solution shown in Figure 1 performs the following four basic tasks: ringing the ring, issuing DC signals to the main exchange and providing a voice path, and monitoring the DC loop. Ringing from the main control panel can be received in the basic circuit state. HK and LV relays are released.)

The HF relay will pull on the 25 Hz ring voltage. The circuit is open due to DC1, C12 capacitors, but the AC current passes through the transformer coils TR, the C1I, C12 capacitors and the resistors R11, R12, R13 to the Graetz rectifier constructed from diodes D1 to D14. From the direct current generated by the Graetz rectifier, the HF relay is drawn and the C14 capacitor is charged. The C14 capacitor filters the pulsating direct current. The Z13 Zener diode protects the HF relay and the C14 capacitor from potential overvoltage. The pulled HF relay contacts the ground to the PBX scanning circuit. The circuit is signaled by closing or looping the DC signal. break down. The loop closes when the HK relay is pulled and the loop is broken when the HK relay is released.

If the "b" branch of the main panel has a negative voltage and the "a" branch is earth, the HF relay draws in the DC circuit.

In this state, the circuit is also suitable for speech transmission.

The TR transformer has low direct current resistance and high resistance to speech frequencies. The capacitors C111, 02 connect the resistors R11, R12, R13 and the diodes D11, D12, D13, D14 in alternating current. In the case of an outgoing call, the circuit can issue dial pulse sequences to the exchange as an option signal. My pulse pulses are released by breaking the DC loop. The DC loop is interrupted by the HK relay according to the instructions issued by the control unit. The LV relay should be pulled when issuing pulse sequences, to minimize the impedance of the dial.

The circuit can also cooperate with a main exchange which signals the disconnection of the calling subscriber on branches "a" and "b" by reversing the circuit.

Such a switchboard enables the implementation of a "trunk clock" service in the switchboard. By default, the negative line must be connected to the "b" branch of the circuit and the positive (earthed) branch to the "a" branch of the main line. The main panel reverses this polarity and this pole reversal is detected by the HF relay.

The circuit according to the invention shown in Figure 2 is as follows:

The main exchange is connected to the tariff receiver 1 on the "a" and "b" branches, which tariff connection 1 is connected to the PBX by wiring h on the one hand and ringing receiver 2 by additional wires on the other. The ring receiver 2 comprising Graetz diode switching, resistor and capacitor is connected to the loop polarity monitoring circuit 3 via the parallel connected varistor VA and to the optical interface CS1 of the interface circuit I via the Graetz switching photodiode. The loop polarity monitoring circuit 3 is connected to the controlled power supply 4 and is connected to the PBX via this wire. The controlled power consumer 4 is via the 2/4 wire converter 5, through its wires c and d with the PBX, the optical connector CS2 of the interface circuit I and the contact L of its relay A, and the loop output and pulse control pulse control circuit 6 via its control output VI. is related. The loop and disk short-pulse pulse control circuit 6 is connected via wires g to the PBX and output V2 to the interface circuit I.

One embodiment of the controlled power consumer 4 is known, e.g. No. 172,780. HU patent. The 5 2/4 wire converter is a hybrid circuit known in the art of transmission. The 6 loops and pulse short pulse control pulse control circuit are suitable for the MOTOROLA MC 14409 integrated circuit (available in MOTOROLA TELECOM catalog 1983).

-3193107

The elements of the interface circuit I which are important to the invention and their connection are operated by the figure.

The operation of the circuit according to the invention is as follows:

Signals from the main control panel (ring, DC, speech) on the "a" and "b" wires first pass to the tariff receiver 1, then on to the ring receiver 2, after the surge protection variator VA, to the loop polarity monitoring circuit 3 and then to the controlled power supply. 5 to a 2/4-wire converter and from there through c and d wires to proper digital filtering and amplification, and after A / D, D / A conversion. The loop polarity monitoring circuit 3 transmits information from the main line to the PBX via the interface circuit I via the interface circuit I and the transceiver 2. And the PBX transmits its control signals via the g wires to the integrated loop 6 loop and disc pulse controller. This circuit usually serves as a dial-up circuit for telephone sets and is recommended by the manufacturer for such use.

The transistor collector of the optical coupler CSI of the ring receiving circuit 2 provides a base current to the output transistor T2 from the positive supply voltage, since the emitter of the optical coupler CSI is connected to the base of the output transistor T2. The base current of the output transistor T2 is shunted by the transistor T1 by switching its collector and emitter between the base and emitter of the output transistor T2, and the base of the transistor T1 can be controlled via resistor R1 by the loop and pulse circuits. The control signal from V2 output can provide a triple control function due to the switching arrangement: it resolves the blocking of the 2 ring receivers via resistor R1, provides deactivation during dialing by actuating relay A and controls the dial short circuit through the optical coupler CS2, the same current as the relay coil A passes through its diode. The control output VI controls the loop closing and loop breaking of the controlled power consumer 4. Capacitor C delays the operation of the ringer 2. The tariff receiver 1 sends information to the PBX via the h line. Advantageous properties of using the present invention. can be summarized as follows: The bell receiving circuit 2 can be disabled simultaneously with the corresponding optical coupler CSI and transistor T2 and with the same control signal that controls the deafing relay A, in addition, the dc switching dc switch 4 connected to the relay A it also controls the disc lock. A further advantage of the circuit according to the invention is that it allows the short-circuit state of the disc to be produced without high current surges by connecting the relay coil A to the optical coupling diode CS2 and the inductance of relay A preventing a steep current surge.

Claims (2)

PATENT CLAIMS 1. A circuit arrangement for the production of a mainline circuitry for telephone exchanges comprising a circuit-switched tariff reverse circuit, a high impedance blockable ring receiving circuit (with electronic components), a surge protection varistor, a loop polarity monitoring circuit, a controllable power supply, a 2/4 wire comprising a circuit characterized in that the ring receiver (2) comprises a high sensitivity optical coupler (CSI), the loop polarity monitoring circuit (3) comprises an optical coupler, the controlled power consumer (4) has a ground-symmetrical design, the loop and pulse short-circuit 6) one control output (VI) is connected to the controlled power supply (4), the other control output (V2) is connected to an interface circuit (1) which is connected to the controlled power supply (4) by the output circuit (I) The switching circuit (I) is connected to the ringing receiver (2) via an optical coupler (CSI). Circuit arrangement according to Claim 1, characterized in that the collector of the optical coupler (CSI) of the ring receiving circuit (2) is connected to the positive supply voltage by its collector and its emitter is connected to the base of the output transistor (T2). a positive supply voltage and an additional transistor (TI) collector to the base of the output transistor (T2), and the emitter of the shunt transistor (TI) is connected to ground potential along with the emitter of the output transistor (T2) and the delay capacitor (C) is connected in parallel. With its collector and emitter (TI) and the base of the shunt transistor (TI), it is connected via a resistor (R1) to the coil of the dimmer relay (A), which coils in series with a diode of an optical coupler (CS2).