JPH0321110Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a circuit for forming a DC loop in a circuit through which a DC signal is superimposed with an AC signal, and particularly relates to a DC loop forming circuit suitable for pulse relay.
This DC loop forming circuit is applied, for example, to various trunks of telephone exchange equipment (key telephone equipment, private branch exchanges, etc.).

[Prior art]

In a telephone trunk of a telephone exchange, a direct current signal on which an alternating current signal (voice, etc.) is superimposed is applied to a telephone line. Here, the above-mentioned communication line has no attenuation of the AC signal due to the call (even if there is attenuation, the amount is extremely small), and it is in a closed state in terms of DC to control the start-up of the other party's switching equipment. Requires a DC loop forming circuit to create.

A typical DC loop forming circuit is a circuit using a letter coil, but with the computerization of telephone exchange equipment, electronic circuit elements have come to be used in the DC loop forming circuit. I'm getting old. As a DC loop forming circuit using such electronic circuit elements, for example, the one shown within the dotted line in FIG. 3 has been used in the past.

As described above, the DC loop forming circuit requires a circuit that exhibits a relatively low resistance value (approximately 150 ohms) to DC current and high impedance to AC signals. The circuit within the dotted line in FIG. 3 is a circuit that satisfies this requirement. In other words, a current (a direct current with an alternating current signal superimposed) flowing to the communication line flows through the transistor Q through the resistor _R2 , but since the alternating current signal superimposed on the current is bypassed by the capacitor _C1 , the transistor Q A constant current flows between the collector and emitter regardless of the amplitude of the AC signal. This action means that only direct current flows through transistor Q,
This means that no AC signal flows, which satisfies the above requirements. Note that the current flowing through the resistor _R2 and the capacitor _C1 (including the AC signal component) is extremely small (the resistance value of the resistor _R2 is set to a relatively large value). This does not mean that AC impedance is low.

FIG. 3 is a circuit diagram of a main part showing a conventional example of a trunk of a telephone exchange device constructed using the above-mentioned circuit.

In this conventional trunk, when relay A operates to form a closed loop with the central office line,
When the contact a closes _, a current flows through the _DC loop circuit, but as shown in FIG. The base current of transistor Q gradually increases, and the current flowing through the emitter and collector of transistor Q also gradually increases and reaches a constant value. As described above, it takes a relatively long time for the response of the DC loop forming circuit to form a closed loop. The operation (changes in current between the collector and emitter of transistor Q) cannot quickly follow the period of the dial pulse, and therefore the dial pulse relayed by the circuit becomes extremely distorted. For this reason, in the past, as shown in Figure 3, a relay B was provided, and the relay B was operated during dial pulse relay, and its contact b separated the DC loop forming circuit and formed a closed loop with respect to the station line. ing.

[Problem that the invention attempts to solve]

As explained above, conventionally, the operating time of the DC loop forming circuit is long, so it is impossible to form a DC loop by itself when relaying dial pulses. A separate loop forming circuit means (relay B described above) is required.

The present invention is proposed to solve these problems, and it also makes it possible to form a DC loop during dial pulse relay by itself. It is an object of the present invention to obtain a DC loop forming circuit that can omit circuit means.

[Means for solving problems]

For the above purpose, the present invention connects a series circuit including a capacitor and a diode between the collector and base of the transistor of the DC loop forming circuit, and directs the charging current flowing to the capacitor at the moment when the communication current is applied. The operation of the transistor is accelerated by introducing the voltage into the base circuit of the transistor and rapidly raising the base potential of the transistor.

[Configuration of Example]

FIG. 1 is a circuit diagram showing an embodiment of the present invention. Note that this embodiment is implemented for the central office line trunk TRK.

In Figure 1, A is a relay that closes a DC loop to the office line and relays dial pulses, a is its contact, and BR is a relay that controls the communication current even if the office line changes polarity. A diode bridge to ensure that the flow direction is always constant, Q is a transistor to set the impedance of the DC loop, and D is to prevent AC signals (audio signals, etc.) from flowing to the base of transistor Q. T is a transformer for relaying AC signals, P and S are its primary and secondary coils, respectively, R ₁ is a resistor for compensating the impedance of the DC loop, R ₂ is a transformer for transistor Q. Resistor for specifying base current value, R ₃
is a resistor for controlling diode D to turn off,
C ₁ is a capacitor that bypasses the AC signal applied to the base circuit of transistor Q, C ₂ is a capacitor that accelerates the rise of the operation of transistor Q, blocks DC current, and allows only AC signals to pass. ₃ is a capacitor to lower the impedance to AC signals.

The communication line is extended to the telephone side via a DC loop forming circuit mainly composed of contact a of relay A, diode bridge BR, and transistor Q, and transformer T.

The office line is connected to the AC terminal side of the diode bridge BR, and the communication line extending to the telephone side is connected to the diode bridge BR DC terminal. When a DC loop is formed due to the presence of the diode bridge BR, the polarity of the communication line is always constant regardless of the polarity of the office line (in Figure 1, the upper side is (+) and the lower side is (-). ).

The transistor Q has its collector connected to the (+) side of the communication line, its emitter connected to the (-) side of the communication line via the resistor _R1 , and the connection between the base and collector of the transistor Q. (Between the base and the communication line (+) side) is a resistor R ₂ ,
A capacitor C ₁ is connected between the base and the emitter (between the base and the communication line (-) side), and a capacitor C 2 is connected to the base of the transistor Q from the (+) side of the communication line, and a capacitor C ₂ is connected to the primary side of the transformer T. A series circuit in which a coil P and a diode D are connected in this order is connected.

The diode D is connected in such a direction that its cathode side becomes the base side of the transistor Q, and a resistor R ₃ and a capacitor C ₃ are connected between its anode and the (-) side of the communication line. ing.

In the configuration described above, the feature of the present invention is clearly shown by the capacitor C ₂ and diode connected between the (+) side of the communication line (collector of transistor Q) and the base of transistor Q. D
is in a series circuit containing.

[Effect of the embodiment]

FIG. 2 is a time chart showing the operation of the embodiment.

Transistor Q, resistors R ₁ and R ₂ , capacitor
The circuit consisting of C ₁ has the same configuration as the conventional example,
This circuit exhibits low resistance to direct current,
The circuit exhibits high impedance to AC signals.

Loop control for the central office line is performed by turning on/off relay A from the control section.

When relay A operates in response to a signal from the control section, contact a closes and direct current flows through the communication line. This direct current flows into capacitor _C2 as a charging current,
As shown in FIG. 2, while the value is above the set value, the diode D is turned on and the charging current flows into the base circuit of the transistor Q, rapidly charging the capacitor _C1 . This state is clearly expressed by the difference in waveforms of capacitor _C1 shown in FIGS. 2 and 4.

Note that the primary winding P of the transformer T inserted between the capacitor _C2 and the diode D has almost no effect on the above operation. In other words, since a telephone with a typical characteristic impedance of 600Ω is connected as a load to the secondary winding S of the transformer T, the coupling coefficient between the primary and secondary sides of the transformer T is set to approximately 1. (It is fully possible to bring the coupling coefficient close to 1 by using a material with high magnetic permeability for the core of the transformer T.)
Like the period, the inductance of the primary winding P and secondary winding S of the transformer T and the mutual inductance between the two windings cancel each other out, and the charging current at the base of the transistor Q The transformer T inserted into the inflow path of the telephone can replace the characteristic impedance (600Ω) of the telephone, and since the characteristic impedance (600Ω) of the telephone is relatively small (therefore, it can be considered as a pure resistance). (There is no large error in this case.) This is because it has almost no effect on the above-mentioned charging current flowing into the base.

As a result of the above operations, the base potential of the transistor Q rapidly rises, and the transistor Q rapidly shifts to a steady state (the state after the transition period in which the resistance value between the collector and emitter changes). do. Note that this transistor Q operates in a linear region where it is not completely on because the base current is supplied from the same location as the collector.

As a result of the above operation, the resistance between the collector and emitter of transistor Q rapidly changes from infinity (off state) to relatively low DC resistance (about 100 ohms), and as a result, the DC loop resistance of the telephone line decreases. From infinity to set value Z (collector of transistor Q,
(the sum of the emitter-to-emitter resistance and the resistance _R1 ).

As described above, the change in DC loop resistance when contact a closes proceeds quickly, so the dial pulse is not distorted as shown in FIG. 2 (even if there is distortion, the degree of distortion is very small). ) is relayed correctly.

Note that when the contact a changes from closed to open, the loop is opened at the contact a itself, so the dial pulse waveform is not distorted at this point.

When the direct current loop of the telephone line is completed, a direct current with an alternating current signal superimposed flows through the telephone line (when talking on the telephone), but at this time, the diode D
The anode of becomes (-) potential through resistor R ₃ ,
Since the cathode is at a (+) potential via the resistor _R2 , the diode D is turned off, and the AC signal does not flow to the base circuit of the transistor Q. That is, the DC loop forming circuit exhibits high impedance to AC signals.

Furthermore, in order to control the diode D, a resistor _R3 is inserted into the loop through which the AC signal of the communication line flows, and in order to prevent the AC signal from being attenuated by this resistor _R3 , a capacitor _C3 is connected to the resistor R3. ₃ is installed in parallel. i.e. capacitor
_C3 is a capacitor for bypassing AC signals.

As described above, even if the DC loop forming circuit has a relatively low resistance to DC current, the AC signal flows through the primary coil P of the transformer T with a large amount of attenuation, so it does not interfere with telephone conversation. It will never occur.

[Effect of idea]

As explained above in detail, the present invention connects a series circuit including a capacitor and a diode between the base and collector of a transistor for forming a DC loop, and connects the current flowing through the capacitor when forming a DC loop to the base circuit of the transistor. is applied to accelerate the operation of the transistor and improve the startup of the DC loop.This allows relaying signals that turn on and off in short cycles, such as dial pulses, to a separate DC loop using a relay. can be done without the need to form a loop, and also
Since the operation of the transistor due to the charging current to the capacitor described above is unrelated to the voltage of the telephone line,
The present invention has remarkable effects such as very stable operation.

[Brief explanation of the drawing]

Fig. 1 is a circuit diagram of an embodiment of the present invention, Fig. 2 is a time chart explaining the operation of the embodiment of Fig. 1,
FIG. 3 is a circuit diagram of the conventional example, and FIG. 4 is a time chart showing the operation of the conventional example of FIG. Main symbols: A...Relay for DC loop closure, dial pulse relay, a...Contact of relay A, Q...
...Transistor for setting DC loop impedance, D... Switching diode for cutting off AC signal, C ₁ ... Capacitor for bypassing AC signal, C ₂
...DC blocking, base current increase capacitor,
R ₂ ...Resistance for base current supply.

Claims (1)

[Scope of utility model registration request] A transistor whose collector and emitter are connected between two lines of the communication line, and a first transistor whose collector and emitter are connected between the base of the transistor and a line on the collector side of the communication line.
and a first capacitor connected between the base of the transistor and the line on the emitter side of the communication path, and the communication current flows to the base of the transistor via the first resistance. In the circuit in which the transistor is conductive to form a direct current loop of a communication path, the series circuit includes a second capacitor and a diode,
A series circuit in which the connection direction of the diode is in the forward direction with respect to the base current of the transistor is connected between the collector and base of the transistor with the second capacitor on the collector side and the diode on the base side. and a second resistor connected between the connection point of the diode and the second capacitor and the line on the emitter side of the communication path.