KR940001496Y1 - Tone generator - Google Patents

Abstract

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Description

Output fault detection circuit of call signal generator for electronic exchange

1 is an overall block diagram showing the present invention.

2 is a detailed circuit diagram showing a call signal generation detection unit of the present invention.

3 is a detailed circuit diagram illustrating an alarm signal generator of the present invention.

4 is a waveform diagram of each part of the call signal generation detection unit of the present invention.

5 is a detailed circuit diagram illustrating a redundant control unit of the present invention.

Explanation of symbols for main parts of the drawings

11: call signal output unit 12: call signal generation detection unit

13 redundancy control unit 14 alarm signal generating unit

15: relative call signal output unit 100: relay drive circuit

R1 to R7: Resistor C1 to C3: Condenser

B1 to B5: Buffer I1 to I4: Inverter

N1: AND gate N2: NAND gate

D1 to D3: Diode T: NPN transistor

The present invention relates to an output failure detection circuit of a call signal generator for an electronic exchange in which a call signal generator for an electronic exchange generates an alarm signal when a call signal is not output properly.

Conventional call signal generators do not know whether the call signal generator is broken because there is no device to inform even if the call signal is not properly output, and once a failure has a problem that it is difficult to operate until the device is repaired.

For this reason, in order to increase the reliability of the system, a redundant configuration of the call signal device is essential, and thus, an output failure detection circuit is required.

Therefore, the object of the present invention is to detect the 20Hz sinusoidal AC voltage signal required for the call signal of the called subscriber, and if the call signal is not output properly, the alarm signal is sent through the alarm signal generator, and the call in the standby state through the redundant control unit. The present invention provides an output failure detection circuit of a call signal generator for an electronic exchange for improving the maintenance and reliability of the call signal device by supplying the call signal by switching to a signal output unit.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall block diagram showing the present invention.

In the drawing, 11 denotes a call signal output unit of a call signal device, 12 denotes a call signal generation detector, 13 denotes a redundancy control unit, 14 denotes an alarm signal generator, and 15 denotes a call signal output unit of a standby call signal device.

The present invention is connected to the call signal output unit 11 of the call signal device for outputting a 20 Hz sinusoidal AC voltage signal (700 Vrms ~ 90 Vrms) by a relay, the call signal generation detection unit 12 for detecting whether or not the call signal is generated, A redundancy control unit 13 for supplying a relay driving signal for switching to a standby standby call signal output unit 15 using the signal output from the call signal generation detection unit 12, and the call signal generation detection unit 12; The alarm signal generator 14 is connected to the redundancy control unit 13 and transmits a failure signal.

FIG. 2 is a detailed circuit diagram showing the call signal generation detection unit 12 of the present invention, and the operation waveform thereof is shown in FIG.

In the figure, D1 represents a diode, R1 to R3 represents a resistor, I1 represents an inverter, C1 represents a capacitor, and 21 represents a monostable multivibrator. The call signal detector is connected to a diode D1, a resistor R1 connected to the cathode of the diode D1, an inverter I1 connected to the resistor R1, and an inverter I1, and a resistor R3 and a capacitor. A monostable multivibrator 21 including (C1) and one end is connected between the resistor (R1) and the inverter (I1) and the other end is composed of a resistor (R2) that is grounded as follows: .

When the call signal output (4 degrees (a)), which is a 20 Hz sinusoidal alternating signal, is generated, the signal attenuated by the distribution circuit of the resistors R1 and R2 after half-wave rectification (4 degrees (b)) through the diode D1 ( 4 degrees (c) is supplied as an input signal of the inverter I1 so that the output of the inverter I1 is used as the trigger pulse signal (four (d)) of the monostable multivibrator 21 and the output of the triggered signal. Is maintained as a low state signal for a predetermined time determined by the values of resistor R3 and capacitor C1, and if a call signal output does not occur, a -48V voltage is maintained at the diode D1 as it is. The signal passing through the distribution circuit of R2) is passed through the inverter I1, and the signal is received by the monostable multivibrator 21 to make it a high state signal to be maintained as a high state signal for a predetermined period.

3 is a detailed circuit diagram of the alarm signal generator 14 of the present invention.

In the figure, I2 represents an inverter, D2 represents a light emitting diode, R4 represents a resistor, and B1 represents a buffer.

The alarm signal generator 14 includes a buffer B1 connected to the assertion multivibrator 21, an inverter I2, a light emitting diode D2 connected to a cathode end of an output terminal of the inverter I2, and the light emitting diode. It consists of a resistor (R4) connected to the anode end of (D2) and operates as follows.

When the call signal is generated, the monostable multivibrator 21 maintains the output signal as a low state signal and informs the steady state through the butter B1. The low state signal passes through the inverter I2 and emits light. The normal state is indicated by the light off. In addition, when the call signal is not generated, the output signal of the monostable multi-vibrator 21 is maintained as a high state signal to inform the alarm state through the buffer B1, and the high state signal is transmitted through the inverter I2. Alarm status is indicated by lighting of D2).

5 is a detailed circuit diagram illustrating the redundancy control unit 13 of the present invention.

In the figure, R5 to R7 are resistors, C2 and C3 are capacitors, B2 to B5 are buffers, I3 and I4 are inverters, N1 is an AND gate, N2 is a NAND gate, D3 is a diode, T is an NPN transistor, and 100 is The relay drive circuit is shown.

The redundancy control unit 13 has an AND gate N1 connected to an input terminal of the resistor R5 and the inverter I3, a buffer B2 connected to an output terminal of the AND gate N1, and an input terminal connected to the inverter I3. An output of the buffer B3 having the enable terminal connected to the call signal generation detection unit 12 and a NAND gate N2 to which a Vcc voltage is applied, a transistor T having a base terminal connected to an output terminal of the NAND gate N2, A diode D3 having an anode terminal connected to the collector terminal of the transistor T, a buffer B5 connected to an enable end of the buffer B3, an inverter I4 connected to an enable end of the buffer B3, A buffer B4 connected to the inverter I4 and a capacitor C3 having one end connected to an input terminal of the inverter I3 and the other end grounded.

The redundancy control unit 13 is for controlling the redundant call signal generating device in an operating state and a waiting state, and generates a warning signal after generating an alarm signal when the operating call signal generating device malfunctions. This is to improve the maintenance and reliability of the call signal generator by operating.

TABLE 1

Table 1 shows signal states of the redundancy control unit 13.

First, the description of the circuit in the steady state is as follows.

When the call signal generation detection unit 12 normally generates a call signal, the state signal becomes low and informs the normal state through the enable end of the buffer B3. In a non-normal state, the state signal becomes high and the buffer B5. ) To alert you of an alarm condition. In the call signal generator in operation, the high state signal input S1 is applied to the AND gate N1, and the high state enable signal input E1 is applied to the inverter I3. Accordingly, the state signal output SO becomes high and the enable signal output EO goes low, and the relay drive circuit 100 including the NAND gate N2, the transistor T, and the diode D3 is provided. A low state input is applied to drive a relay (not shown). In this case, the relay driving circuit 100 uses a bumper IC chip that is generally used. The state signal output SO and the enable signal output EO of the call signal generator in operation are respectively the state signal input SI and the enable signal input EI of the call signal generator in operation. The alarm signals of the call signal generator being used are all output as a low state, and the relay (not shown) of the call signal generator, which is a standard, is not driven.

Next, when the call signal generator becomes abnormal and the call signal is not generated, the high signal is output through the buffer B5 of the call signal generator in operation to inform the alarm state and the enable signal input E1 is low. The state signal output SO goes low, the enable signal output EO goes high, and the relay drive circuit 100 goes off. Therefore, the status signal input (SI) of the waiting call signal generator is turned low, the enable signal input (EI) is turned high and the waiting relay driving circuit is on. It becomes

As described above, the present invention can reduce the cost by simple circuit configuration, and it is economical, and it has a self-diagnostic function, which is easy to maintain and redundant, so that reliability is greatly improved.

Claims (4)

In the output failure detection circuit of the call signal generator for an electronic exchange, an alarm for connecting to the call signal generation detecting means (12) and the call signal generation detecting means (12) for detecting whether a call signal has been generated or not, to inform an alarm state. The signal generator 14, the call signal generation detection unit 12 and the alarm signal generator 14 is connected to the call signal generator for an electronic exchange, characterized in that it comprises a redundancy control means 13 for redundancy operation. Output failure detection circuit. The method of claim 1, wherein the call signal generation detection unit 12 is connected to the diode (D1) for rectification, the inverter (I1) connected to the diode (D1), the inverter (I1) to maintain a signal for a predetermined time Output failure detection circuit of the call signal generator for an electronic exchange, characterized in that it consists of a monostable multivibrator (21). The method of claim 1, wherein the alarm signal generator 14 comprises an inverter I2, a light emitting diode D2 connected to the inverter I2, and a buffer B1 connected to an input terminal of the inverter I2. An output failure detection circuit of a call signal generator for an electronic exchange. The logic of claim 1, wherein the redundancy control means (13) is connected to a first inverter (I3) to which an enable signal input (EI) is applied, a logic connected to the first inverter (I3), and to a state signal input (SI). The first means to the multiplication means (N1), the first buffer (B3) connected to the first inverter (I3), the relay driving means (100) connected to the first buffer (B3), the call signal generation detection unit 12 And a second inverter (I4) connected in parallel with the enable end of the buffer (B3).