SK500152010A3 - Method of setting decisive parameters of track circuit with digital track receiver and feeding end in order to achieve greater resistance to endangering currents - Google Patents

Abstract

The method of setting the decisive parameters is carried out by a calculation. In the first step during the unoccupied state (VS) of the track circuit (KO) all of the track circuit's (KO) considered combinations of discrete values (H) of power supply end equipment setting elements (NPN) and receiver end equipment setting elements (NPP), are set after the chosen steps (ZK), to find the optimum phase angle (ao), between the track voltage (UK), which is induced from the power supply track voltage (NUK), and between the reference voltage (UR) for the unoccupied state (VS) of the track circuit (KO). The state of emergency (HS) and shunt state (SS) of the track circuit (KO) is calculated for this optimum phase angle (ao). In the second step, the track circuit's (KO) power supply end equipment setting elements (NPN) and receiver end equipment setting elements (NPP), are corrected, according to the considered combination of power supply end equipment setting elements (NPN) and receiver end equipment setting elements (NPP). The goal is to find the track circuit's (KO) resultant phase angle (av). Thus, the first set of values for the optimum configuration (NPNO) of the power supply end (NK) equipment setting elements (NPN) and the second set of values for the optimum configuration (NPPO) of the receiver end (PK) equipment setting elements (NPP) of the track circuit (KO), are determined, until finding the most favourable mutual conditions, for the track circuit's (KO) shunt state (SS) and simultaneously the state of emergency (HS). The lowest possible track voltage during a state of emergency (UKH) is subsequently chosen so, that the lowest possible corresponding track voltage level in the shunt state (UKS) is found. The resulting value (VHN) of the power supply end setting elements and the resulting value (VHP) of the receiver end setting elements found in this manner, are fast set, for the track circuit's (KO) value of the power supply end (NK) equipment and value of the receiver end (PK) equipment found in this manner, and thereby also the resulting phase angle (av) between the track circuits (KO) track voltage (UK) and between reference voltage (UR) found in this manner.

Description

The invention relates to a method of adjusting critical parameters of a track circuit with a digital track receiver and a power supply end to achieve higher resistance to hazardous currents. The method is carried out by safely evaluating the freedom or occupancy of the track circuit by the rolling stock by means of power supply end adjustment elements and receiving end adjustment elements, while evaluating the shunt condition.

BACKGROUND OF THE INVENTION

In rail circuits with a digital rail receiver, the method of adjusting the critical parameters of the rail circuit to achieve higher resistance to endangered currents has not yet been solved economically and has not been used. This is disadvantageous because, as a result, the rail circuit with the digital rail receiver does not achieve the required or possible resistance to the hazardous currents. At the same time, the occurrence of hazardous currents is much more frequent and at a much higher intensity due to the introduction of new powerful powertrains and propulsion vehicles with asynchronous engines, as was the case in the past when using pulse width control of traction drives of vehicles and units. vehicles with asynchronous engines. This was adversely reflected in the insufficient level of resistance parameters of the track circuits against the endangered currents. This immunity is required on the basis of the requirements of the technical specifications for interoperability between traction units or traction units and between track circuits.

Available modern solution of resistance of electronic track circuits against threatening currents is evident from CZ 296 242 of 26 November 2004. It is a solution where a correct voltage component as well as a contractually deformed voltage component are introduced into the track circuit. In this way, it is possible to safely evaluate the freedom or occupancy of the rail section on the basis of a mathematical analysis. The disadvantage of this solution is the difficult generation and application of the contractually deformed stress component. In particular, this method requires the demanding equipment of the staff performing the regulation, maintenance and service of the track circuits thus conceived with measuring instruments.

Another available solution for safe evaluation of rail circuit freedom is evident from CZ 297 033 dated July 16, 2003. This embodiment of the invention does not eliminate the effect of hazardous currents with the necessary efficiency, so that safe evaluation of rail section freedom or occupancy is not functionally efficient enough. This issue is also dealt with in the solution according to utility model CZ 15508 dated May 11, 2005 with an electronic phase-sensitive track receiver. It is an analog system of an electronic phase-sensitive receiver whose resistance to hazardous currents is based on an increased tripping factor. This solution, similar to the solution of the two-phase rail receiver according to the invention CZ 257 559, is based on the already outdated concept of resistance to current currents, based on an increased tripping factor. This resistance is higher than the usual level for these solutions at the time, but it is still roughly half the value recommended by the TSI (Technical Specification Interoperability) of the European Standardization Institute “CENELEC”.

SUMMARY OF THE INVENTION

Said disadvantages of the prior art solutions are eliminated or substantially reduced by adjusting the critical parameters of the track circuit with the digital track receiver and the power supply end to achieve a higher endurance current resistance according to the present invention.

SUMMARY OF THE INVENTION In the first step, in the free state of the track circuit, all considered combinations of discretized values of the power end device adjusting elements and the receiver end device adjusting elements of the track circuit are adjusted after selected steps different from the nominal value of the power end adjusting elements. and from the nominal value of the receiving end adjusting elements by one percent. The adjustment in this first step is carried out as long as an optimum phase angle is found between the rail voltage, which is derived from the supply rail voltage, and between the reference voltage for the free state of the track circuit. For this optimal phase angle, the emergency state and the shunt state of the track circuit are calculated.

In a second step, the power end gear adjuster and receiver end track adjuster elements change in a second step according to the combinations of power end gear adjuster and receiver end adjuster combinations considered, in steps of steps differing by the order of percent from the respective values. optimum state according to the first step so that the aim is to find the resulting phase angle of the track circuit. Therefore, for this purpose deter2

SK 288183 B6 mines a plurality of optimum configuration of power end device adjusting elements and the optimum configuration of the receiver end device adjusting elements of the track circuit where the conditions for the shunt state and the track circuit emergency are mutually favorable. What is the procedure for selecting the rail stresses in the emergency state as low as possible so that a correspondingly low value of the rail stress in the shunt state is found. Then, for the thus obtained power end equipment values and for the thus obtained receiver end equipment values of the track circuit, the resultant value of the power end adjustment elements and the resultant value of the receiver end of the track circuit are thus fixed and thus the resulting phase angle between the rail voltage. and a track circuit reference voltage, for example, in the form of track circuit configuration data with a digital track receiver and a power end.

Preferably, a very accurate measurement of the reference voltage value is continuously performed, including all interference and endangering components of the reference voltage that can be induced into the reference voltage circuits from the vicinity of the track circuit with the digital track receiver and the supply end. Thus, the voltages generated by the hazardous currents are measured such that when an above-the-threshold value of these interference and hazardous components of the reference voltage is detected, the digital track receiver is commanded to safely disarm it so that the given track circuit with the digital track appears safe as a receiver. by rolling stock.

The main advantage of the method of setting the critical parameters of the track circuit with a digital track receiver and with the power supply end is to achieve a higher resistance against hazardous currents. These parameters are optimally calculated and then the phase ratios between the track voltage and the reference voltage are set unambiguously, based on the optimization of the shunt and emergency conditions objectively, ie without the negative influence of the human factor. This process greatly speeds up the activity in question and shortens the related railway exclusion. Another advantage is the fact that in case of occurrence of above-the-limit components of the voltage at the reference voltage, the given electric track section of the given track circuit is immediately occupied, thus preventing a dangerous condition in a timely manner and occurring failure is reported or manifested in time.

Another advantage is that the setting of the critical parameters of the track circuit, ie their parameterization, is part of the configuration data. It is implemented one time before the commencement of the operation of the track circuit with a digital track receiver based on optimization of the shunt and emergency state, depending on the length of the track circuit and the specific leakage admittance.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is described in detail in the exemplary embodiment shown in the accompanying drawings, in which FIG. 1 shows a generalized schematic representation of a track circuit, FIG. 2 shows a vector diagram of phase dependence; and FIG. 3 shows the discretization of the resultant values of the adjusting elements.

DETAILED DESCRIPTION OF THE INVENTION

In this exemplary embodiment, shown schematically in FIG. 1, 2 and 3, a method of setting critical parameters of a track circuit KO with a digital track receiver DKP and a power supply end NK to provide a higher resistance to the endangered IR currents is described. The method is further elucidated on the basis of the vector diagram shown in FIG. 2, which illustrates the course of the rail voltage UK relative to the reference voltage UR. The search for the optimum and resultant values of the NPN power end adjuster elements NK and the NPP receiver end adjuster elements PK of the track circuit KO is apparent from FIG. Third

In the first step, in the free state VS of the track circuit KO, all considered combinations of discretized values H (Fig. 3) of the adjusting elements NPN and the adjusting elements NPP of the receiver end of the rail circuit KO are adjusted after selected steps ZK differing from the nominal NHN adjusting elements NPP of the power supply end NK and from the nominal value of the NHP adjusting elements of the receiver end of the track circuit equipment KO by the order of one percent; so that an optimum phase angle α (Fig. 2) is found between the rail voltage UK, which is derived from the supply rail voltage NUK and the reference voltage UR for the free state VS of the track circuit KO. For this optimal phase angle α, the emergency state HS and the shunt state SS of the track circuit KO are calculated.

In a second step, there is a further change of the power end device NPN adjusting elements and the NPP receiver end adjusting elements of the track circuit KO according to the considered combinations.

The step of adjusting the NPN power end adjuster elements and the receiver end gear NPP adjuster elements in steps, varying by percent, from the values pertaining to the optimum state of the first step, so as to find the resulting phase angle α in the track circuit KO. Therefore, a plurality of optimum NPNO configuration values of the power end equipment adjustments and a plurality of NPPO optimum configuration settings of the receiver end equipment PK adjustments of the KO track circuit are determined such that the conditions for the shunt state SS and the emergency state HS of the track circuit KO are mutually favorable. Therefore, a procedure is chosen in which the rail voltage UKH is selected as low as possible in an emergency condition, so that the corresponding lowest value of the rail voltage UKS at the shunt state SS is found. For this way, the resultant VHN value of the power end adjusting elements and the resulting value VHP of the adjusting elements of the receiver end are fixed for the thus obtained power end equipments NK and for the receiver end equipments PK of the rail track KO. the phase angle α between the rail voltage UK and the reference voltage UR of the rail circuit KO, for example in the form of the rail circuit configuration data KO with the digital rail receiver DKP and the supply end NK.

A preferred way of adjusting the critical parameters of the track circuit KO with the digital track receiver DKP and the power supply end NK to achieve higher resistance to the endangered currents IR is apparent from the general schematic drawing of the embodiment shown in FIG. 1. In this case, a very accurate measurement of the reference voltage UR, including all interference and endangering components of the reference voltage URR, that can be induced into the reference voltage circuits UR from the surroundings of the KO circuit with the digital rail receiver DKP and the power supply end NK. Thus, such voltages generated by the hazardous currents IR are measured. Therefore, when the URRn limit value of the interference and threatening components of the reference voltage is detected, the digital track receiver DKP is commanded to safely disarm it so that the given track circuit KO with the digital track receiver DKP safely appears to be occupied by the rolling stock KV.

Industrial usability

As can be seen from the above description, the method of setting critical parameters of a KO circuit with a digital rail receiver DKP and a power supply end NK to achieve higher resistance to endangered currents IR can be used in the new construction of railway safety devices with KO circuit with digital rail receivers. as in existing rail circuits. In particular, the invention finds application on all electrified lines on which high-performance traction vehicles and asynchronous drive units, whose emission of hazardous currents reaches high to above-limit values in accordance with applicable standards, are to be driven.

Claims (2)

1. A method of setting critical circuit parameters (KO) with a digital track receiver (DKP) and a power supply end (NK) to achieve higher immunity to hazardous currents (IR) by safely evaluating the freedom or occupancy of a track circuit (KO) by a rolling stock (KV) by power supply end (NK) and receiving end (NPP) adjusting elements (NPN), evaluating the shunt state (SS) and the emergency state (HS), characterized in that in the first step they are set at the open circuit (VS) of the track circuit (KO) all considered combinations of discretized values (H) of the power end device (NK) adjusters (NPN) and the receiver end device (PK) adjusters (NP) of the track circuit (KO) after selected steps (ZK) differing from the nominal value (NHN) of the power supply end adjuster (NPN) and the nominal value (NHP) of the adjuster the NPP of the receiver end of the track circuit equipment (KO) by one percent until finding the optimal phase angle (oo) between the rail voltage (UK) derived from the supply rail voltage (NUK) and the reference voltage (UR) ) for the free state (VS) of the track circuit (KO); provided that for this optimum phase angle (σ) the emergency state (HS) and shunt state (SS) of the track circuit (KO) are calculated; wherein, in a second step, the previous adjustment of the power end device (NK) and the end element (NPP) of the receiver end (NP) of the track circuit (KO) is corrected according to the combinations of the power end device (NPN) ) and adjusting elements (NPPs) of the receiver end gear (PK) step by step differing in units of percent from the values belonging to the optimum state according to the first step until finding the resulting phase angle (s) of the track circuit (KO). the NPNOs of the power end gear adjusting elements, and the second set of NPPOs The track end receiver (KO) equipment features until the most favorable condition is achieved for the shunt state (SS) and at the same time for the emergency state (HS) of the track circuit (KO); consequently, the line voltage (UKH) at the emergency state is selected as low as possible to find the corresponding lowest value of the rail voltage (UKS) at the shunt state (SS); for this, the resultant value (VHN) of the power supply end (NK) adjusting elements (NPN) and the resultant value are fixed for the thus obtained values of the solder end (NK) equipment and for the receiver end (PK) equipment values (VHP) of the receiver end (PKP) adjusting elements (NPP) and thereby the resulting phase angle (av) thus found between the track voltage (UK) and the reference voltage (UR) of the track circuit (KO), preferably in the form of track circuit configuration data ( KO) with digital track receiver (DKP) 10 with power end (NK). Method for adjusting the critical parameters of a track circuit (KO) with a digital track receiver (DKP) and a supply end (NK) to achieve a higher endangered current (IR) resistance according to claim 1, characterized in that the reference voltage values are accurately measured continuously (UR) including all reference voltage and interference (URR) components that can be induced into the reference voltage (UR) circuits from around the track circuit (KO) with the digital track receiver (DKP) and the power end (NK); and potential voltages generated by the hazardous currents (IR) are also measured, so that when the above-the-limit (URRn) value of the interference and hazard components of the reference voltage is detected, the Digital Track Receiver (DKP) is commanded to safely de-energize it. ) with the Digital Rail Receiver (DKP) safely appears to be contained by the Rolling Stock (KV).