SU919140A1 - Device for interfacing telegraphic apparatus - Google Patents

Description

 The invention relates to telegraphy. A device for coupling telegraph devices is known, which contains a local power source, the negative pole of which is connected to the cathode of the transmitting optocoupler LED and the emitter of the photoreceiver of the receiving optocoupler, the collector of which is connected to the first output of the first telegraph separator, the second input of which is connected via the first telegraph receiver. a resistor with the anode of the transmitting optical diode LED, the collector of the photoreceiver of which is connected via a linear power source to the first input of the second cart afnogo apparatus, wherein the emitter pho topriemnika transmitting photocoupler connected to the anode of the LED of optocoupler receiver, and the third output of the first telegraph connected to the positive pole of the local power source 1. However, in the known device not provided interfacing with four- telegraph communication channels. The purpose of the invention is to provide the interface of the telegraph apparatus, included in the three-wire circuit, with the four-wire communication channels. To achieve the goal, a telegraphic interface device containing a local power source, the negative pole of which is connected to the cathode of the LED of the transmitting optocoupler and the photodetector emitter of the receiving optocoupler, whose collector is connected to the first output of the first telegraph apparatus, the second output of which is connected the anode of the LED of the transmitting optocoupler, the collector of the photodetector of which is connected through a linear power source to the first input of the second telegraph apparatus, and The emitter of the photoreceiver of the transmitting optocoupler is connected to the anode of the LED of the receiving optocoupler, and the third output of the telegraph device is connected to the positive pole of the local power source, a second resistor is inserted, a condenser diode, an additional optocoupler and an inverter, the first output is connected to the cathode of the receiver. The optocoupler's anode of the photodetector is connected to the second output of the first telegraph apparatus, the first output of which is connected to the first input of the inverter, the second input of which is connected to the second the output of the inverter and with the phototherm emitter of the receiving optocoupler cathode of which is connected to the first output of the second resistor and to one output of the capacitor, the other output of which is connected to the anode of the additional optron and the anode of the diode whose cathode is connected to the cathode of the photodiode of the additional optocoupler , with the second input of the second telegraph apparatus and with the second output of the second resistor. The drawing shows a structural electrical circuit of the proposed device. The device contains a transmitting optocoupler 1, receiving optocoupler 2, additional optocoupler 3; inverter | linear power supply 5, local power supply 6, resistor 7 / capacitor 8, diode 9, resistor O, telegraph devices 11 and 12, The device operates as follows. 8, the source state through the contacts of the transmitter 13 of the telegraph apparatus 12 is closed the power supply circuit of the light output of the transmitting optocoupler 1, as well as the power supply circuit of the electromagnet through the output of the inverter 4. In this case, the transmitting optocoupler 1 is open and the power supply circuit of the telegraph apparatus 11 of the key of the linear power supply 5 is open, photodetector of the transmitting optocoupler 1, the LED of the receiving optocoupler 2, resistor 7, K-pemma 15, line 16 of communication, telegraph device 11, line 16 of communication, terminal 17, minus linear power supply 5, When working from its body When the currentless signals are sent, the LED circuit of the transmitting optocoupler 1 breaks and it breaks the linear circuit. When current is sent, the linear circuit is restored. Thus, information is transferred from the telegraph unit 12 to the telegraph unit 11. The operation of the telegraph unit 12 is carried out by chains; plus local power supply 6, transmitter contacts 13, electromagnet 14, normally closed inverter output t, minus local power supply 6. It should be noted that for current premises arriving in a line, capacitor 8 is charged, and for current-free premises it is discharged along the circuit: left (positive) capacitor plate 8, resistor 7, additional optocoupler 3 LED, right (minus) capacitor plate 8, However, when the capacitor 8 is discharged through the LED of the additional optocoupler 3), the thyristor of this key is not turned on, because the contacts of the transmitter 13 of the telegraph unit 12 with the fuzzy messages the power supply circuit of the thyristor is broken. Therefore, when operating from the telegraph unit 12 (despite the linear circuit breaks), the thyristor of the additional optocoupler 3 js therefore, the output of the inverter 3 remains closed, ensuring the photoreceiver of the receiving optocoupler 2 is bypassed. and the voltage on the thyristor of the additional optocoupler 3 is maintained all the time. At the beginning of the first currentless transmission from the telegraph unit 1 I, the capacitor 8 is discharged through the LED of the additional optocoupler 3, the thyristor of which is turned on, the inverter k is activated, the output of the inverter i |. disconnecting and shunting the output of the receiving optocoupler 2 stops for the entire time of transmission from the telegraph unit 11, since the thyristor of the additional optocoupler is switched on all the time and one input of the inverter is under voltage. For currentless signals from the telegraph apparatus 11, the power supply of the LED of the receive optocoupler 2 is interrupted and its photodetector breaks the power supply circuit of the electromagnet 14. When a current parcel arrives from the telegraph apparatus 11, the receiving optocoupler 2 opens into the electro 59

magnet 1A receives the current parcel along the circuit: plus the local power source 6 power supply contacts of the transmitter 13. electromagnet. a receiving optocoupler of the optocoupler 2. minus the local source of 6 power.

Thus, information is received from the telegraph apparatus 11.

When resuming transmission from the telegraph unit 12 during the starting send, the power supply circuit of the thyristor of the additional optocoupler 3 and the inverter is cut off. By the output of the inverter k, the photodetector of the receiving optocoupler 2 is shunted and this position is maintained until work begins on the part of the telegraph apparatus 1 1.

In the absence of a communication channel, the power supply circuit of the electromagnet 1 of the telegraph apparatus 12 is closed through the output of the inverter k and it is possible to check the telegraph apparatus, that is, it does.

To connect the telegraph unit 12 to the four-wire communication channel, the jumper between terminals 18 and 19 is removed. The transmitting branch of the communication channel is connected to terminals 17 and 18, and the receiving branch of the channel - to terminals 15 and 19. The receiving branch of the communication channel is powered from the side of the calcium-forming equipment.

Thus, in the proposed device, it is possible to interconnect a telegraph apparatus connected in a three-wire pattern with metro-conductive communication channels.

Claims (1)

Invention Formula A device for interfacing the telegraph apparatus (; c, containing a local power source, the negative pole of which is connected to the cathode of the LED the transmitting optocoupler and the photodetector emitter of the receiving optocoupler, the collector of which is connected to the first output of the first telegraph apparatus, the second output of which is connected through the first resistor to the anode of the transmitting optocouple diode, the collector of the photoreceiver of which is connected through a linear power source to the first input of the second telegraph apparatus, moreover, the emitter of the photoreceiver of the transmitting optocoupler is connected to the anode of the LED of the receiving optocoupler, and the third output of the first telegraph apparatus is connected to the positive With a local power source, which is different from the fact that, in order to interface the telegraph apparatus, connected in a three-wire circuit, with four-wire communication channels, a second resistor, a capacitor, a diode, an additional power supply terminal and an inverter, the first output of which is connected to the cathode of the photodetector of the additional optocoupler, the anode of the photodetector of which is connected to the second output of the first telegraph apparatus, the first output of which is connected to the first input of the inverter, the second input of which is connected to the second output of the investment rtora and with the photodetector emitter of the receiving optocoupler, the cathode of which LED is connected to the first output of the second resistor and to one output of the capacitor, the other output of which is connected to the anode of the LED of the additional optocoupler and the anode of the diode, the cathode of the additional optocoupler to the second input the second telegraph apparatus and with vporyy A output of the second resistor. Sources of information taken into account in the examination 1, UK Patent M4b5571 cl. H 3 F, 1977 (prototype).