SU652012A1 - Contact-less digital code decoder - Google Patents

Description

The invention relates to railway telemechanics and is intended for use in numerical code auto-locking and automatic locomotive signaling.

Known contactless decoders. the numerical code, which contains the input busbars, into which, respectively, the locking and disconnecting contacts of the impulse path relay connected via the insulating junction of track circuits in parallel with the transmitter, blocking oscillators, rectifiers, amplifiers and coincidence units are inserted.

However, known decoders have significant drawbacks. The presence in them, in particular, electrolytic capacitors of large capacity significantly reduces their operational reliability. In addition, in known devices there is no control of the short-circuit of the insulating joints of the track circuit, and the signal indications are very limited.

Also known is a contactless decoder of a numerical code containing input rails with closing and opening contacts of a pulsed traveling relay, contacts of a transmitter relay, a push-pull register, to the reset inputs of which a pulse driver is connected, and control outputs 3 are units of signalization 3.

This contactless decoder also does not exclude the random change of signal indications of a traffic light in the event of a short circuit of the isolating joints, including in this, and a short-term appearance of more permissive fire, since the recording of units in

register cells can also be produced by extraneous impulse.

The purpose of the invention is to increase the reliability during short circuit of insulating joints.

five

Claims (3)

The goal is achieved in that the contactless code decoder is equipped with inverters and delay triggers, while the control input and the synchronization input of the first delay trigger are connected respectively via the break contact of the transmitter relay to the zero bus and via the first inverter to one of the input buses connected to the second delay trigger trigger input, the sync input connected via the second inverter and the closing contact to the zero bus, and the output to the zero input input of the first delay trigger, n The set inputs of the unit of both triggers are connected to the other input bus, and the outputs of the first delay trigger are connected to the information inputs of the register. . FIG. 1 shows a functional diagram of a contactless decoder of a numeric code when implementing two signaling channels; in fig. 2 - time diagram of the most characteristic functional elements. The decoder contains a push-pull register consisting of 1, 2, 3, 4 cells, to the reset inputs of which a driver of 5 pulses is connected, and alarm control units 6 are connected to the control outputs. Each alarm unit includes a series-connected switch 7, a capacitor drive 8, a blocking generator 9, a trigger 10, an amplifier P, and a signal relay 12. In addition, the decoder contains input slots 13 and 14, two inverters 15 and 16, a closing 17 and disconnecting 18 contacts of the trans. relay relay (not shown), two delays flip-flops 19 and 20. One of the delay triggers 19 has a control input 21, a synchronization input 22, a zero setting input 23, a unit installation input 24 and outputs 25 and 26. Another delay trigger 20 has a control input 27, a synchronization input 28, a unit setting input 29 and an output 30. The decoder works as follows. In the initial state, in all cells of register 1–4, zeros are written, and in triggers 19 and 20 - ones, on the bus 13 there is a single potential, on the 14th level, left. When the first code pulse arrives, the bus potentials change their values at the output of the inverter 15, and therefore at the synchronization input 22 of the trigger 19, a voltage drop from 0 to 1 occurs. If the break contact 18 was closed before, the trigger 19 will come to the zero state, since a zero potential is applied to its control input 21 (moment t, in Fig. 2). A change in the potentials at the outputs 25 and 26 of the flip-flop 19 will result in writing 1 in the cell 1 of the register. The resulting difference, the voltage on the control (single) output, acts on the key 7, closing it for a short time, due to which the capacitor in the accumulator 8 is charged. After the end of the effect of the voltage drop, the switch 7 reopens and receiving inverse power from the capacitor of accumulator 8, it generates short pulses with high duty cycle. In this case, the absolute value of the voltage across the capacitor gradually decreases (see Fig. 2). The pulses from the blocking oscillator 9 are fed to the counting input of the trigger 10, due to which the latter produces oscillations of a rectangular shape. These oscillations are amplified and rectified by the subscriber 11, which ensures the continuous operation of the signal relay 12. In the event of a short-circuit of the isolating junctions in the trigger 19, the O recording will not be produced under the influence of an extraneous pulse, since the voltage drop across its synchronization input 22 caused by code pulse of an adjacent circuit, occurs after the opening contact 18 is open. However, whenever a pulse of its own circuit comes before an adjacent pulse, an O record in trigger 19 will be produced. After the end of the first code pulse, the flip-flop 19 comes back to the initial state (recorded 1), as a result of which the writing of the unit in the cell 2 of the register will occur. When a long interval occurs, the shaper 5, having a pulse input, produces a reset pulse (time moment f leading the register cells to its initial state. When the next code cycle pulse arrives (time point ta), the O record will not trigger 19 as the code pulse is sent to the 7-junction circuit at this moment — an impulse and contact 18 are open, For the same reason, O will not be recorded at the beginning of the next cycle (time tj. in Fig. 2). However, O will be recorded at time Is in trigger 20, since this mo The ent is closed contact 17 and at the output of the inverter 16, and therefore, at the input 28 of the synchronization of the trigger 20, a difference from 0 to 1 will occur, and the control input 27 from the bus 13 will receive 0. Since the output 30 of the trigger 20 is connected to the input 23 setting zero of trigger 19, then, O will write down, which will result in 1 in cell 1 and charging capacitor g of storage 8. charging O in trigger 20 can occur under the action of only a pulse of its own rail circuit, regardless of the state of the isolating joints, after the termination of the trigger pulse s 20 and 19 come to the initial state (time 1), and, at time * P register will be reset. The maximum time during which a capacitor in storage 8 does not receive a charge is about two code cycles, in accordance with which and; should select its capacity. The described descrambler has an advantage over the known one in that its operation does not depend on the state of the insulating joints, i.e. the signal of the traffic light will correspond to the code received from its track circuit regardless of the presence of a short-circuit of the insulating joints. This will increase the reliability of the autolock and will reduce the delay of trains on the stretch. A non-contact numeric code decoder containing input buses with closing and opening contacts of a pulse track relay, contacts of a transmitter relay, a push-pull register, to the reset inputs of which a pulse driver is connected, and control outputs have signaling blocks characterized in that increase the reliability in case of short circuit of insulating joints, it is equipped with inverters and delay triggers, while the control input and the input of the syngy .. h her.1 e, 7 synchronization of the first delay trigger is connected, respectively, via the disconnecting contact of the transmitter relay to the zero bus and through the first inverter to one of the input buses connected to the control input of the second delay trigger, the synchronization input connected via the second inverter and the closing bus act to the zero bus and the output to the input of setting the zero of the first delay trigger; moreover, the installation inputs of the unit of both triggers are connected to another input bus, and the outputs of the first delay trigger to the information inputs register. Sources of information taken into account during the examination 1. USSR author's certificate No. 150124, cl. In 61 L 23/14, 08.21.63. 2. USSR author's certificate number 206630, cl. B 61 L 23/14, 08,12.67. 3. USSR author's certificate number 518408, cl. B 61 L 23/14; 06.25.76. -1 Pgf 1ZHNZ-ENE