SK49697A3 - Realtime activated crossing safety device - Google Patents

Abstract

The crossing safety device (CSD) has equipment for time-conditioned warning (TCW) attached through a crossing communication channel (CCC) to the centre (C) located at the first station (100) where the train stops. The centre (C) is connected to the vehicle device (VD) by means of a radio communication channel (RCC). The warning signalled by the crossing safety device (CSD) is calculated by the centre (C) on the basis of the distance of the railway crossing (RC) from the first station (100) where the train stops and basis of other parameters and the real time of the warning is safely communicated by the centre (C) to the crossing safety device (CSD), which initiates the warning when the real time of the warning comes into effect. The train is permitted to leave the first station (100) in line with the train timetable, taking into account possible delays, and after safely registering the command to initiate the warning by the crossing safety device (CSD) in line the calculated real time of the initiation of the warning. The warning ends after the train has gone through the railway crossing (RC) after evaluation by the cancellation file (CF).<IMAGE>

Description

Technical field

The present invention relates to the real-time activation of an automatic roadside interlocking device on railway lines, without the use of means for detecting the presence of a train in the rail sections adjacent to the crossing, i.e. in the approach sections. Only the real-time time-dependent cross-border alert means operating in conjunction with the train detection means is used to control the operation of the roadside protection devices according to the invention.

BACKGROUND OF THE INVENTION

Previously known automatic roadside interlocking devices used, in addition to means for detecting the passage of the train through the annulment section, always means for detecting the presence of the train in the approach sections of the given roadside interlocking device. In most cases, this method of evaluating the presence of a train is used by long parallel circuits with low frying voltage or by point means such as axle counter sensors and the like, which significantly increases the investment and operating costs of the signaling equipment, particularly in terms of consumption. electricity, despite the fact that in recent years, due to worsened emissions of air pollutants, there has been an increased occurrence of corrosion of the running surfaces of the rails and thus a deterioration of the train's shunting capability, which significantly compromises the safety function . The parallel track circuits can also be removed by using an automatic pass-through signaling device that does not require a means of detecting the presence of a train in which the conditional alert means consist of a safe time file and the associated logic. The disadvantage of this solution is the requirement of fixed lines.

SUMMARY OF THE INVENTION

The above deficiencies are eliminated by having the first terminal of the central terminal being connected to the first terminal of the real-time receiver, the second terminal of the central terminal being connected to the second terminal of the real-time receiver, while the third terminal of the central terminal is connected to the first terminal of the traveling communication channel. the third terminal of the communication channel is connected to the first terminal of the security device, the fourth terminal of the communication channel is connected to the second terminal of the traveling security device, while the third terminal of the traveling signaling device is connected to the first terminal of the receiver of the real transit time, wherein the fourth terminal of the travel protection device is connected to the second terminal of the real transit time receiver.

English Translation:

The advantages of the circuitry according to the invention are that, for example, satellite links or other switched networks without mass lines can be used for the connection between the central and the interlocking device, in which the traffic delay is stochastically dependent. A further advantage is that only train crossing means and a time-dependent crossing signal means are used to safely convert the conditional alert into a real-time real-time alert, calculated on the basis of the distance of the crossing from the train dispatching station, at incline ratios. the line, the maximum line speed, the timetable and any possible train delays. In the device according to the invention, it is no longer necessary to use means for the safe delay of time and, on the one hand, means for detecting the presence of a train in the rail sections adjacent to the crossing, i.e. in the approach sections. In most cases, up to now parallel track circuits or secure point means such as axle counter sensors and the like serve this safe way of assessing the presence of a train, which considerably increases the investment and operating costs of the signaling equipment, in particular as regards electricity consumption. . Using the invention

- 3 there will also be savings in sizing power supply systems and cabling for parallel track circuits in the approach sections, which is a significant cheaper travel-to-go alarm. The progress achieved by the invention is further that the removal of parallel track circuits removes the degraded train shifting ability that has been occurring in recent years due to the increased existence of corrosion-causing impurities in the air and the increased occurrence of rail corrosion.

The application of the circuit according to the invention will therefore greatly increase the safety of the function of the roadside interlocking device compared to the hitherto known solution using parallel track circuits.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 shows an example of a configuration of stations and a real-time traversal interlocking device and an embodiment of an automatic traversal interlocking device according to the invention. In FIG. 2 shows an example of a configuration of stations, a real-time cruise control device and a vehicle to which information is transmitted from the center, and an example of an embodiment of an automatic cruise control device according to the invention when driving permitting or disabling information to a train leader.

DETAILED DESCRIPTION OF THE INVENTION

Figure 1 shows an example of a real-time activated real-time protection interlock device where the first terminal C1 of the central C receiver is connected to the first terminal RCC1 of the real time RCC receiver, the second terminal C2 of the C terminal is connected to the second RCC2 terminal of the real time RCC receiver. while the third terminal C3 of the central office C is connected to the first terminal PKK1 of the PKK pass-through communication channel. the fourth terminal C4 of the central control unit C is connected to the second terminal PKK2 of the PKK2 travel path. wherein the third terminal PKK3 of the PKK pass-through communication channel is connected to the first terminal PZS1

4 of the PZS 14 and the fourth PKK4 of the PKK 4 are connected to the second PZS2 terminal of the PZS. while the third terminal PZS3 of the PZS is connected to the first terminal RCP1 of the real-time RCP receiver, and the fourth terminal PZS4 of the PZS4 is connected to the second RCP2 of the RCP receiver. In the same figure, a block arrangement of critical functional units according to the invention is shown below, wherein the first station 100 is the train dispatching station, while the second station 200 is the station to which the train is dispatching. The sign PZS is a security device and the sign P The sign L indicates the departure signal

The central unit C is equipped with the first central unit communication block 1C, the second central unit communication block 2, the central unit or dispatcher service station and an automatic AJC input of the roads, which are connected to the control unit of the RBC center. The PZS is equipped with an AS cancellation file, a PZ peripheral, and a CPV crossing alerts, which mainly includes a KP crossing block, the HP internal clock marked with a crossing is a crossing, for an odd driving direction.

conditional communication crossing and the MP memory of the crossing.

In FIG. 2, the fifth terminal C5 of the central station C is connected to the first terminal RKK1 of the radio communication channel RKK, the sixth terminal C6 of the central station C is connected to the second terminal RKK2 of the radio communication channel RKK. while the third terminal RKK3 of the radio communication channel RKK is connected to the first terminal VZ1 of the on-board equipment VZ. wherein the fourth terminal RKK4 of the radio communication channel RKK is connected to the second terminal VZ2 of the onboard vehicle equipment VZ, while the first terminal RCV1 of the real time RCV of the vehicle is connected to the third terminal VZ3 of the vehicle equipment VZ. the second real-time RCV receiver terminal RCV2 of the vehicle is connected to the fourth terminal VZ4 of the on-board vehicle equipment VZ. The vehicle vehicle VZ is equipped with a vehicle KV communication block, a vehicle MV memory and an internal clock HV of the vehicle computer, which is corrected by the received real time data from the real-time RCV receiver of the vehicle.

FIG. 1 is a clear principle of operation of the real-time travel protection device. In a situation where a train is dispatched from the first station 100 to the second station 200, i.e. towards the crossing P on the initiative of the dispatcher, which is mediated by the central office or dispatcher service station 0, possibly on the initiative of the AJC The RBC of the central office is the real time when the PZ peripheral device on the PZS interlocking device is to be alerted. This time is calculated on the basis of the distance P from the first station 100, as well as the maximum line speed and the slope conditions of the line and, in particular, the timetable and possible train delay, where the maximum possible train acceleration must be considered. In the headquarters RBC control block, the real time is generated by the central clock of the central computer HC, which is corrected by receiving real time information via the real time RCC receiver. The conditional alert initiation request is sent to the CPV time conditional alert through the first communication block 1KC of the central office, further through the PKK transit communication channel. which can be, for example, radio and via a communication block KP crossing.

conditional alert is

The receipt of this request is confirmed by the receipt of a return telegram transmitted from the CPV time conditional alert to the RCB headquarters control block. In the second step, based on the positive result of the verification of the implementation of the first step, the command to initiate the conditional alert is transmitted from the central control block RBC to the CPV means of the time-based alerts. Both this command and the first conditional alert initiation request are expressed by the calculated real alert initiation time with an acceptable time tolerance. The real time is measured by the internal clock HP crossing the CPV of the time conditional crossover alert, and these hours are corrected by the real time data received by the real time RCP receiver. After comparing the accuracy of the two data stored temporarily in the CPV time-based crossing alert,

In CPV, temporarily stored request.

the positive result of this comparison recorded in the MP memory of the crossing. The essential content of the result of this comparison is the real time, which indicates when the alert should be initiated at the PZS. A confirmation message is sent from the crossing memory MP to the control block RBC that a warning at the crossing crossing P will be initiated at this time. The calculated real departure time of the train from the first station 100 to the second station 200 respects the timetable data and the possible delay of the train.

In FIG. 2 shows an exemplary embodiment of the invention when, in addition to the solution according to FIG. 1, driving permitting or forbidding information is still transmitted to the leading vehicle of the train. The principle of operation is that, for example, the first preliminary approval for train departure is transmitted from the RBC control block to the VU vehicle via the second 2CC communication block. the RKK radio communication channel and the KV communication block of the vehicle. This information is temporarily stored in the vehicle's VZ equipment. The receipt of this request is confirmed by the receipt of a return telegram sent from the on-board unit VZ to the control block of the RBC central unit. Communication with the interlocking security device PZS follows. which gives a first conditional level crossing alert as explained in the apparatus of FIG. 1. In the next step, based on the positive result of verifying the implementation of the first step, leaving the control block, the second conditional approval is transmitted to the RBC of the central office to the on-board vehicle equipment. Both this consent and the first conditional exit consent are expressed in terms of the calculated real departure time with an acceptable time tolerance. The real time on the vehicle is generated by the internal clock HV of the vehicle computer and these hours are corrected by the real time RCV received by the real time RCV receiver. In the case of a positive result of the comparison of the contents of both messages stored temporarily in the on-board vehicle VZ, the result of this comparison is recorded in the memory of the vehicle MV. The essential content of this final report is real time, which indicates when the departure of the vehicle can start. This departure is possible when the real time that is recorded is reached. The recording of this information, i.e. to execute only this real-time memory, automatically evaluates the exit of the vehicle to the memory MV of the vehicle is sent from the vehicle equipment VZ to the control block RBC of the central office and to the CPV of the time conditional alert. Until this information is received, there will be no further communication between the RBC control unit and the CPV of the time-based crossover warning, thus preventing the vehicle from departing towards the P crossing. Alternatively, a limited number of repeated communication cycles between the RBC control block and the vehicle alarm The VZ can manage to match the messages to be compared, eliminating the malfunction. In trouble-free mode, the train will depart at the calculated time and a warning will be signaled to the road user in time for P. This warning shall be terminated when the train passes through the crossing through the AS, or any other known means indicating the train's crossing and direction. The CPV means that the time conditional alert will be set to the ground state, based on the operation of the transition detecting means and the train's direction of travel. This makes the PZS roadway safety device ready for a warning when another train is running. In order to ensure the safety of the operation of the device according to the invention, both the central unit C and the CPV means of the time-based cross-border alert and also the vehicle equipment VZ are implemented by microprocessor means using known conjunctive or majority redundancy principles. For example, the dual channel hardware arrangement of all the microprocessor means of a whole. Any failure of one of the channels of these devices is carried in a safer direction, which is disagreement on the train's departure towards level P, in the absence of the conditions for timely warning. In the event that a train has already departed towards a level crossing and one of the device channels fails, the alert must be immediately after the occurrence of this situation, ie before the calculated alert time. Given that the likelihood of such a case is very low, this procedure is necessary in the interests of the safety of the function of the device, even at the cost of giving excessive warning to road users in this exceptional case.

then it will be initiated

Industrial usability

The automatic roadside interlocking device according to the invention can be used in new construction, but especially in the reconstruction of roadside interlocking devices on the railway. The application of the automatic roadside interlocking device according to the invention will have a considerable economic effect on secondary and less loaded railway lines, where an automatic line interlocking device is not built and where it will not be necessary to build and maintain parallel track circuits in approaching and departing sections.

Claims (2)

PATENT CLAIMS 1. A real-time travel control signaling device, characterized in that the first terminal (C1) of the central unit (C) is connected to the first terminal (RCC1) of the real time center receiver (RCC), the second terminal (C2) of the central unit (C) is connected to the second terminal (RCC2) of the real time clock receiver (RCC), while the third terminal (C3) of the central station (C) is connected to the first terminal (PKK1) of the travel communication channel (PKK), is the fourth terminal (C4) ) connected to a second terminal (PKK2) of the roadway communication channel (PKK), the third terminal (PKK3) of the roadway communication channel (PKK) is connected to the first terminal (PZS1) of the roadway interlocking device (PZS) and the fourth terminal (PKK4) (PKK) is connected to the second terminal (PZS2) of the roadside alarm (PZS), while the third terminal (PZS3) of the roadside alarm (PZS) is connected to the first terminal u (RCP1) of the real-time traverse time receiver (RCP), wherein the fourth terminal (PZS4) of the travel-side protection device (PZS) is connected to the second terminal (RCP2) of the real-time traverse time receiver (RCP). The road signaling device according to claim 1, characterized in that the fifth terminal (C5) of the central office (C) is connected to the first terminal (RKK1) of the radio communication channel (RKK), the sixth terminal (C6) of the central office (C) being connected. to a second radio communication channel (RKK2) terminal (RKK), while a third radio communication channel (RKK3) terminal (RKK3) is connected to a vehicle terminal (VZ1) first terminal (VZ1), while a fourth radio communication channel (RKK4) terminal (RKK4) RKK) is connected to the second terminal (VZ2) of the on-board equipment (VZ), while the first terminal (RCV1) of the real-time receiver (RCV) is connected to the third terminal (VZ3) of the onboard equipment (VZ). a real-time vehicle receiver (RCV) connected to the vehicle terminal (VZ4) fourth terminal (VZ4).