RU213416U1 - Track circuit pulse signal receiver - Google Patents

Abstract

The utility model relates to pulse signal receivers in track circuits and can be applied in the field of railway automation. The essence of the utility model lies in the receiver of pulse signals in track circuits, containing a housing that includes a block for receiving pulse signals from the track circuit, a block for generating information signals for processing in the control unit, an output relay control unit, an output interface and a power supply connected to them, while the output relay control unit contains an additional channel for switching between the front and rear signals of the output relay, made with the possibility of reserving the main channel upon receipt of the corresponding signal from the control unit. The technical result consists in reducing the risk of failure of the receiver of impulse signals of the track circuit. 3 w.p. f-ly, 1 fig.

Description

The utility model relates to pulse signal receivers in track circuits and can be applied in the field of railway automation.

As a prototype, a receiver of impulse signals of a rail circuit of the brand IVG-Ts was selected, including a unit for receiving pulse signals from a rail circuit, the output of which is connected to an information signal generation unit for processing in a control unit, the input of which is connected to the information signal generation unit, and the output is connected to an output relay control unit containing one channel for switching between the front and rear signals of the output relay, an output interface and a power supply connected to them, while the receiver contains a control relay control unit [General description IVG-C: https://web.archive. org/web/20220531093423/http://stalenergo.ru/?page_id=1522%2A; IVG-Ts functional diagram: http://stalenergo.ru/wp-content/uploads//2016/02/rukovodstvo_po_ekspluatacii3.pdf, accessed 05/31/2022].

The disadvantage of the prototype is the high risk of failure of the receiver pulse signals of the rail circuit due to a malfunction in one or more elements of the channel for switching between the front and rear signals of the output relay. As a result, the front signal will stop coming to the decoder cell through the receiver output interface, as a result of which the decoder will stop outputting signals about the path being busy, disrupting the normal operation of the auto-lock cabinet, which significantly reduces the reliability of the receiver.

The technical problem to be solved by the utility model is the need to improve the reliability of the receiver of impulse signals of the track circuit.

The technical result, to which the utility model is directed, is to reduce the risk of failure of the receiver of impulse signals of the track circuit.

The essence of the utility model is as follows.

The rail circuit pulse signal receiver comprises a housing including a block for receiving pulse signals from the rail circuit, the output of which is connected to the information signal generation unit for processing in the control unit, the input of which is connected to the information signal generation unit, and the output is connected to the output relay control unit, containing one channel for switching between front and rear output relay signals, an output interface and a power supply connected to them. Unlike the prototype, the output relay control unit contains an additional channel for switching between the front and rear signals of the output relay, made with the possibility of reserving the main channel upon receipt of the corresponding signal from the control unit.

The housing provides the carrier function of the track circuit pulse signal receiver. The housing can be made of known dielectric materials that protect the internal components of the receiver from the effects of adverse environmental factors, such as a dielectric composite or polymer.

The block for receiving pulse signals ensures the receipt of pulse signals from the track circuit and their transmission to the block for generating information signals. The block for receiving pulse signals can be made in the form of a relay socket, terminals, cable interface or other detachable electrical connections.

The information signal generation unit provides the transformation of pulse signals into information ones for their subsequent processing in the control unit. The formation unit can be made in the form of interconnected rectifier bridges, smoothing filters, zener diodes and other well-known microelectronic components and structures based on them for converting electrical signals.

The control unit controls the normal operation of the receiver. The control unit provides processing of information signals coming from the formation unit, and also receives and transmits information signals from the output relay control unit and the output interface. The control unit can be made in the form of one or more microcontrollers or microprocessors with peripheral devices connected to it.

The output relay control unit provides channel control for switching between the front and rear signals of the output relay based on the information signal received from the control unit. The channel can be made in the form of a switch connected to the rear and front signal controls.

The output relay control unit contains an additional channel for switching between the front and rear signals of the output relay, made with the possibility of reserving the main channel upon receipt of the corresponding signal from the control unit. This reduces the risk of failure of the output relay control unit due to redundancy in the event of a failure of the main channel, which leads to a decrease in the risk of failure of the receiver of impulse signals of the track circuit as a whole.

The main and additional channels can have an identical layout and can be made in the form of a switch connected to the control elements of the rear and front signals, and the output relay control unit contains a redundancy element connected to the outputs of the rear and front signal control elements and the control unit and is configured to switching the main channel to the additional one upon receipt of the corresponding signal from the control unit.

In this case, the switches can be made in the form of electromagnetic relays on a reed switch or in the form of solid-state opto-relays. The most preferable is the implementation of switches in the form of solid-state opto-relays, since they do not contain mechanically movable elements, resulting in a reduced risk of wear and premature failure, which reduces the risk of failure of the track pulse signal receiver.

The output interface ensures the transmission of information signals from the output relay unit to the decoder cell of the automatic blocking cabinet, as well as the transmission of information signals about the status of the receiver from the control unit to the supervisory control device. The output interface may be in the form of a relay socket, terminals, cable interface, or other pluggable electrical connections.

Power Supply provides generation and supply of supply voltages to each element of the receiver of impulse signals of the track circuit. The power supply can be made in the form of a single unit, or it can be divided into several elements that provide supply voltage to different elements of the receiver.

To further increase the reliability, the information signal generation unit can be made in the form of three identical signal generation elements, the outputs of each of which are connected to the control unit, and the control unit can be configured to compare the signal values received from each signal generation element and disable one or several elements when a malfunction is detected. This makes it possible to reduce the risk of failure of the signal conditioning unit due to duplication of information signals at the output and the preservation of the receiver's operability when one or more formation elements are turned off, which leads to a reduction in the risk of failure of the receiver of pulse signals of the track circuit.

To further increase the reliability, the control unit can be made in the form of two microprocessors connected to each other, while the inputs of each microprocessor can be connected to the output of the information signal generation unit, and the outputs of each microprocessor can be connected to the input of the output relay control unit. This makes it possible to compare the values of the signals received from the information signal generation unit between the microprocessors and makes it possible to detect a malfunction of the receiver if the signals between the microprocessors do not match, thereby reducing the risk of failure of the control unit and the receiver as a whole.

A utility model can be made from known materials using known means, which indicates its compliance with the patentability criterion "industrial applicability".

The elements of the pulse signal receiver of the track circuit can be connected to each other by means of known electrical connection means, such as wires, cables, contact plates or contact tracks.

The utility model is characterized by a set of essential features previously unknown from the prior art, characterized in that the output relay control unit contains an additional channel for switching between the front and rear signals of the output relay, configured to reserve the main channel upon receipt of the corresponding signal from the control unit. This reduces the risk of failure of the output relay control unit by switching to an additional channel in the event of a failure of the main channel, as a result of which the edge signal continues to flow to the decoder cell through the receiver output interface, while maintaining its operability.

This ensures the achievement of the technical result, which consists in reducing the risk of failure of the receiver of impulse signals of the track circuit, thereby increasing its reliability.

The utility model is characterized by a set of essential features previously unknown from the prior art, which indicates its compliance with the “novelty” patentability criterion.

The utility model is illustrated by the following figures.

Fig.1 - Functional diagram of the receiver of impulse signals of the track circuit.

To illustrate the possibility of implementation and a more complete understanding of the essence of the utility model, an embodiment of its implementation is presented below, which can be modified or supplemented in any way, while the present utility model is by no means limited to the presented embodiment.

The rail circuit pulse signal receiver comprises a housing 1, which includes a block 2 for receiving pulse signals from the rail circuit, made in the form of a cable interface, a signal generation block 3 containing three identical signal generation elements 7, a control block 4 containing microprocessors 8, a control block 5 an output relay, an output interface 6 containing a signal output element 13 to the decoder cell and an element 14 for outputting a signal about the state of the receiver to the supervisory control device, as well as a power supply unit that provides the formation of the supply voltages of the above elements. Block 5 contains the main and backup channel for switching between the front and rear signals of the output relay and is configured to reserve the main channel upon receipt of the corresponding signal from the control unit 4. The channels have an identical structure and are made in the form of switches 9, represented by a solid-state opto-relay, rear signal control elements 10, front signal control elements 11 and redundancy element 12.

The output of block 2 is connected to the inputs of the elements 7 of the formation of signals of the block 3, while the outputs of each of the elements 7 are connected to the inputs of the microprocessors 8, which are connected to each other. The outputs of each of the microprocessors 8 are connected to solid-state opto-relays 9 of the main and backup channels, which, in turn, are connected to elements 10 and 11. The outputs of element 10 are connected to the redundancy element 12 and the body bus, and the outputs of element 11 are connected to the redundancy element 12 and to the output interface 6, namely to the element 13 of the signal output to the decoder cell. In addition, the outputs of the microprocessors 8 are connected to the element 12 of the redundancy and the element 14 of the signal output of the status of the receiver to the supervisory control device.

The utility model works as follows.

The track signal receiver is connected to the track circuit pulse signal source, as a result of which the pulse signal is fed to the receiver through block 2, after which it is dubbed into three identical signal generation elements 7 and converted for further processing by microprocessors 8.

Reception of signals from elements 7 of microprocessors 8 is carried out as follows: each microprocessor 8 receives a signal from each element 7, after which each microprocessor 8 first compares the value of the signals from elements 7, and then compares the received signals with the second microprocessor 8. If as a result comparison, it is found that the signal of one of the elements 7 does not match the signals from other similar elements 7, then the microprocessors 8 stop receiving the signal from the faulty element 7 and the fault signal is sent to the supervisory control device through the element 14, while the receiver continues to work in standby mode .

In case of failure of two or three elements 7, microprocessors 8 disable the faulty elements 7 and send a signal to the supervisory control device through element 14 about the transition of the receiver to a protective failure state.

After checking the health of the elements 7, the signal is transmitted through the microprocessors 8 to the solid-state opto-relay 9 of the main channel of the control unit 5 of the output relay. Depending on the value of the signal received by the solid-state opto-relay 9, either the rear contact of the element 10 or the front contact of the element 11 closes. signal output to the decoder cell and the redundancy element 12.

The signals from the elements 10 and 11 are transmitted to the redundancy element 12, which, in turn, transmits them to the microprocessors 8, which check the health of the main channel. In the event that the microprocessors 8 detect a malfunction of the main channel, the microprocessors 8 supply a control signal to the redundancy element 12, as a result of which the transition to the backup channel of the output relay control unit 5 is ensured and the corresponding signal is sent to the supervisory control device through the element 14. This reduces the risk of exit failure of the control unit 5 of the output relay, as a result of which the front signal will continue to flow to the decoder cell through element 13, while maintaining the performance of the receiver.

Thus, the achievement of the technical result is ensured, which consists in reducing the risk of failure of the receiver of impulse signals of the track circuit, thereby increasing its reliability.

Claims (4)

1. The receiver of impulse signals of the rail circuit, containing a housing, including a block for receiving impulse signals from the rail circuit, the output of which is connected to the block for generating information signals for processing in the control unit, the input of which is connected to the block for generating information signals, and the output is connected to the control unit of the output a relay containing one channel for switching between the front and rear signals of the output relay, an output interface and a power supply unit connected to them, characterized in that the output relay control unit contains an additional channel for switching between the front and rear signals of the output relay, made with the possibility of redundant main channel upon receipt of the corresponding signal from the control unit. 2. The receiver according to claim 1, characterized in that the main and additional channels have an identical layout and are made in the form of a switch connected to the control elements of the rear and front signals, and the output relay control unit contains a redundancy element connected to the outputs of the rear and front control elements. front signals and the control unit and is configured to switch the main channel to the additional one upon receipt of the corresponding signal from the control unit, while the switch of the main and additional channels is made in the form of a solid-state opto-relay. 3. The receiver according to claim 1, characterized in that the information signal generation unit is made in the form of three identical signal generation elements, the outputs of each of which are connected to the control unit, and the control unit is configured to compare the signal values received from each signal generation element , and turning off one or more signal generation elements when a malfunction is detected. 4. The receiver according to claim 1, characterized in that the control unit is made in the form of two microprocessors connected to each other, while the inputs of each microprocessor are connected to the output of the information signal generation unit, and the outputs of each microprocessor are connected to the input of the output relay control unit.

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