ES2680394B1 - SYSTEM FOR THE DETECTION OF CUTS IN NEGATIVE CONDUCTOR CABLES AND LEAKAGE CURRENTS IN ELECTRICAL INSTALLATIONS - Google Patents

Description

SYSTEM FOR THE DETECTION OF COURTS IN CABLES CONDUCTORS OF

NEGATIVE AND LEAKAGE CURRENTS IN ELECTRICAL INSTALLATIONS

D E S C R I P C I O N

OBJECT OF THE INVENTION

The object of the present invention is a system for the detection of cuts in negative conductor cables and leakage currents in electrical installations of a railway transport network, including railway networks, high-speed train networks, metro networks, networks tram or trolleybus.

Alternatively, this system could be applied to any electrical installation where it is necessary to monitor cuts and leakage currents of energized cables from the same generator, both AC and DC, and therefore even from a group of batteries.

BACKGROUND OF THE INVENTION

Usually, electrical installations, or electrification, of the rail transport networks electrically feed the motor of the trains that circulate on the tracks. These electrical installations comprise a plurality of electrical substations along the track that transform and rectify the electric current coming from the general supply network and produced by the supplying companies. Each electrical substation comprises at least one power supply cable, or feeder, intended to inject electricity to power the electric motor and at least one negative cable intended to return electricity to the electrical substation.

Currently, electrical installations present problems related to the cuts of the negative conductor cables, also known as lane return cables. The negative conductor cable can be composed of more than one negative conductor cable and therefore the section of this for the electrical substation is the sum of the section of all the negative conductor cables of the same electrical substation.

Usually, these cuts in the negative cables are mainly caused by maintenance tasks of the train track, and the theft of these negative lead wires.

This cut of the negative lead wires can cause, among others, the following effects: imbalance of loads, heating of the negative lead wires, leakage currents, deterioration of the inductive joints and economic cost overruns in the consumption of the substations adjacent electrical installations.

More specifically, load imbalances are caused by the reduction of the section of the negative conductor cable, this produces an imbalance of loads between the electrical substations of the electrical installations that feed the rail transport network. This causes that the affected electrical substation does not contribute the necessary electric charge to the train and the collateral substation assumes that imbalance, surpassing the contracted power of the installation. Which implies a greater economic cost and an overexploitation of the installation, which can lead to breakdowns in the electrical installation itself.

The heating of the cables is caused by the reduction of the section of the returns, that is to say, this produces the heating of the negative conductor cables, being able to give place to fires in the zones next to the train track. As well as the fatigue in the materials that when losing the mechanical properties causes the breakage of the negative conductor cables.

On the other hand, the return by earth of electrified systems in direct current, is responsible for the leakage currents. Leakage currents depend on the degree of insulation of the infrastructure with respect to ground, and on the section of the negative conductor cable. Therefore, a decrease in the section of the cable, leads to this type of leakage currents that penetrate the facilities through pipelines, or metal structures, and that in contact with the ground can cause an electrolytic corrosion that degrades structures of the viaducts and that can cause leakage of liquids in buried conduits, explosion of gases and damage to electrical or telecommunications installations outside the railway line. Additionally, these leakage currents can generate a potential difference that It can be dangerous for people and electromagnetic interference that can affect nearby electronic installations.

Additionally, the total lack of the negative lead wires causes, in normal conditions of the railway circulation, the return of current to return through the signaling lane. As a result, the inductive joints, prepared to withstand a limited intensity pass (around 1000 A), suffer their deterioration due to the overstretch, causing blockage and damage to the track signaling circuits.

Finally, when a negative conductor leads are cut, an imbalance of the loads between substations is created. What causes the electrical substation where the incident has occurred does not inject the electrical intensity for which it was designed, reducing the performance of it. While the nearby electrical substations are distributed the loads of this, causing the overshoot of the power sections contracted with the suppliers. What would generate three effects: overexploitation of the facilities, with the possibility of unnecessary breakdowns and delays in circulation, census economic costs for pricing and costs in the repair of the facilities.

In spite of all these negative effects that the cuts and currents of leakage in negative conductor cables can cause, the method of prevention of them is a visual inspection one by one of said cables. This results in a slow method, which requires planning and a high cost of personnel to inspect all the electrical installations of the rail transport network. As a result, in most cases these cuts are not detected or prevented in time.

Currently, in order to try to detect such cuts in the electrical substations, the lack of the negative lead wires is detected when the negative ground levels previously parameterized in the system are exceeded, which causes the total disconnection of the electrical substation, leaving it out of service when a large number of cables have been disconnected.

Currently, these systems are unable to perform a constant checking and signaling of the status and the number of negative lead wires connected to the electrical substation, but only establishes a maximum value of return intensity from which the electrical substation is disconnected, so neither these failures are detected or prevented in time.

DESCRIPTION OF THE INVENTION

The present invention is a system for the detection of cuts in negative lead wires and leakage currents in electrical installations with a plurality of electrical substations of a rail transport network, such as a DC train network, a train network high-speed AC, or a metro network.

Specifically, this system includes:

• a first current transducer, intended to be linked to at least one of the negative lead wires of at least one of the substations, usually installed in its negative well, to measure the return current,

• a feeder transducer, intended to be linked with at least one positive feeder of the electric substation, to measure the intensity consumed by the positive feeder, that is, the intensity injected by the electric substation into the transport network,

• a ground transducer, intended to be connected to the earth plate in the negative well of the electric substation, to measure the intensity provided by an external power source,

• an alert unit comprising a screen and / or a loudspeaker to generate a visual or audible alarm,

• at least one control unit comprising:

or a first means of communication intended to establish a communication with the intensity transducer, with the feeder transducer and with the ground transducer,

or a memory which in turn comprises instructions for detecting cuts and leakage currents,

or a second means of communication intended to establish a communication with the alert unit,

or a microprocessor linked to the memory, with the first means of communication, and with the second means of communication to detect cuts and leakage currents in negative conductor cables by executing the instructions for detecting cuts and leakage currents of the memory, and notify it, through the second means of communication, to the alert unit so that it notifies an operator through the visual or audible alarm.

Preferably, the feeder transducer comprises a hall effect sensor linked to a first analog / digital signal converter.

Preferably, the intensity transducer comprises a hall effect sensor linked to a second analog / digital signal converter.

Preferably, the ground transducer comprises a hall effect sensor linked to a third analog / digital signal converter.

More specifically, this ground transducer is linked to the earth plate to measure the intensities that can come from outside caused by high voltage lines outside the electrical substation or due to lack of insulation of the train tracks. These currents would be considered as leakage currents from external power supplies and would not be measured by the current transducer since they are not conducted by the negative lead wires.

Preferably, the system comprises a plurality of current transducers intended to be linked with a plurality of negative conductor cables of the electrical substation.

Additionally, the control unit comprises a first comparator of the control unit by means of the instructions for detecting cuts and leakage currents comprised in the memory, comparing the intensity measurements of each of the intensity transducers with each other, and this It allows you to detect the cut of negative lead wires in an accurate way without having to use high sensitivity transducers.

Additionally, this comparison allows determining if there is an imbalance of the loads between the electrical substations adjacent to the electrical substation where the system is installed.

More specifically, the instructions for detecting cuts and leakage currents comprise a modifiable intensity parameter, by an operator through the warning unit, which relates the number of negative lead wires for each current transducer. Additionally, these instructions for detecting cuts and leakage currents make it possible to accurately detect the number of negative conductor cables that present a cut, without the need for a current transducer for each negative conductor cable.

To determine the modifiable intensity parameter that detects the lack of negative lead wires, the number of negative lead wires to be verified in the electrical substation is taken into account. To do this, the number of current transducers required is determined based on the number of negative lead wires to be monitored.

Alternatively, the control unit comprises a second comparator which, by means of the instructions for detecting cuts and leakage currents comprised in the memory, compares the measurement of the current transducer with the measurement of the feeder transducer to detect leakage currents of power supplies external to the transport network in an alternative way to the land translator.

Preferably, the control unit comprises a third comparator which by means of the instructions for detecting cuts and leakage currents comprised in the memory, compares the measurement of the current transducer with the measurement of the feeder transducer to detect leakage currents in the network of transport, so that the third comparator detects leakage current when the current measured by the feeder transducer is greater than the current measured by the return current transducer. Note that if there is more than one intensity or feeder transducer, the measures of these are added respectively, before making the comparison.

Additionally, the control unit comprises an intensity monitoring circuit which, by means of the instructions for detecting cuts and leakage currents comprised in the memory, monitors the intensity measured by the ground transducer, to establish the leakage current of the substation electrical Preferably, the control unit comprises an alarm generating circuit for generating the visual or audible alarm when the leakage current is greater than 300A and reproducing it through the warning unit.

Additionally, the alarm generating circuit is configured to generate a disconnect alarm when the leakage current is greater than 650A and reproduce it through the warning unit (5) so that the operator disconnects the electrical substation.

Preferably, the installation comprises a plurality of current transducers comprising the first current transducer and a second current transducer intended to be linked with a plurality of negative lead wires, so that the first current transducer is linked to a single negative conductor cable and the second current transducer is linked with up to 3 negative lead wires.

Preferably, the installation comprises a plurality of current transducers comprising the first current transducer, the second current transducer and a third current transducer intended to be linked with a plurality of negative lead wires, so that the first transducer of intensity is linked with a single negative conductor cable, the second current transducer is linked with up to 2 negative conductor wires and the third current transducer is linked with from 3 to 5 negative lead wires, depending on the electrical substation.

Preferably, the installation comprises a plurality of current transducers comprising the first current transducer, the second current transducer, the third current transducer and a fourth current transducer intended to be linked with a plurality of negative lead wires, so that the first current transducer is linked with a single cable negative conductor, the second current transducer is linked with up to 2 negative lead wires, the third current transducer is linked with up to 3 negative lead wires, the fourth current transducer is linked with from 4 to 5 negative lead wires , depending on the electrical substation.

Preferably, the installation comprises a plurality of current transducers comprising the first current transducer, the second current transducer, the third current transducer, the fourth current transducer and a fifth current transducer intended to be linked with a plurality of current transducers. Negative lead wires, so that the first current transducer is linked with a single negative lead wire, the second current transducer is linked with up to 2 negative lead wires, the third current transducer is linked with up to 3 lead wires of negative, the fourth current transducer is linked with up to 4 negative lead wires and the fifth current transducer is linked with up to 5 negative lead wires.

Preferably, the screen of the alert unit is a touch screen that allows the operator to modify and interact with the control unit to access the memory and modify the intensity parameters, classify the alarms, perform diagnostics of the electrical installation and obtain information , for example live, of the measurements of the different intensity, feeder and earth transducers.

In this way, a system is obtained that reduces the times in the revision of the connections of the negative lead wires for the maintenance personnel of the railway transport network, without it being necessary to periodically move the maintenance personnel to carry out tasks of preventive maintenance.

Additionally, this system to detect the cut before the complete lack of return intensity in the electrical installation which allows to avoid the extra costs derived from exceeding the contracted power, as well as reduce the delay times that may occur in the circulation of the trains for lack of contribution load on the line. It also allows constant verification of the status of negative drivers against thefts.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of practical realization thereof, a set of drawings is attached as an integral part of said description. where, with illustrative and non-limiting character, the following has been represented:

Figure 1.- Shows a schematic view of the system installed in the railway network.

PREFERRED EMBODIMENT OF THE INVENTION

In a preferred embodiment of the invention, as shown in Figure 1, the system (1) comprises a plurality of intensity transducers (3), a feeder transducer (2), a ground transducer (10), a control unit (4) and an alert unit (5).

The current transducers (3) are hall effect sensors linked to a first analog / digital signal converter installed in the negative well of an electrical substation (6) of the rail transport network (7). Specifically, each hall effect sensor is linked to its group of negative lead wires (8) present in said configured well as established in the control unit (4) of the system (1).

Preferably, the feeder transducer (2) comprises a hall effect sensor, linked to a second analog / digital signal converter, intended to be linked with at least one positive feeder (9) of the electrical substation (6), for measuring the intensity consumed by the positive feeder (9).

Preferably, the ground transducer (10) comprises a hall effect sensor intended to be linked, with a third analog / digital signal converter, with the earth plate (11) in the negative well of the electrical substation (6) , to measure the intensity provided by any external power source.

Preferably, the electrical substation (6) comprises the following numbers of negative lead wires (8), not represented individually, the number and position of the current transducers (3) vary as follows:

• 1 negative conductor cable (8) involves an intensity transducer (3), therefore the verification of the current passing through the negative conductor cable (8) that is connected to the rail.

• 2 negative lead wires (8) involves two current transducers (3), one for each negative lead wire (8) with an intensity ratio of 1 to 1.

3 negative lead wires (8) involves two current transducers (3). One on a negative lead wire (8) and the other on two negative lead wires (8), with an intensity ratio of 1 to 2.

4 negative lead wires (8) involves two current transducers (3). One on a negative lead wire (8) and the other on three negative lead wires (8), with an intensity ratio of 1 to 3.

5 leads of negative (8) implies three current transducers (3). One on a negative lead wire (8), another on a negative lead wire (8) and the third on three negative lead wires (8) with an intensity ratio of 1 to 1 to 3.

• 6 negative lead wires (8) involves three current transducers (3).

One on a negative lead wire (8), another on two negative lead wires (8) and the third on three negative lead wires (8), with a ratio of intensities would be 1 to 2 to 3.

• 7 negative lead wires (8) involves three current transducers (3).

One on a negative conductor cable (8), another on two conducting wires of negative (8) and the third on four leads of negative (8), with a ratio of intensities would be 1a 2 to 4.

• 8 negative leads (8) involves three current transducers (3). One on a negative lead wire (8), another on three negative lead wires (8) and the third on four negative lead wires (8), with an intensity ratio would be 1 to 3 to 4.

• 9 negative lead wires (8) involves three current transducers (3).

One on a negative lead wire (8), another on three negative lead wires (8) and the third on five negative lead wires (8), with an intensity ratio would be 1 to 3 to 5.

• 10 negative lead wires (8) involves four current transducers (3). One on a negative lead wire (8), another on two negative lead wires (8), another on three wires (8) and the fourth on four negative lead wires (8), with an intensity ratio would be 1 to 2 to 3 to 4.

• 11 negative lead wires (8) involves four current transducers (3). One on a negative conductor cable (8), another on two negative lead wires (8), another on three negative lead wires (8) and the fourth on five negative lead wires (8), with an intensity ratio it would be 1 to 2 to 3 to 5.

• 12 negative lead wires (8) involves four current transducers (3). One on a negative lead wire (8), another on two negative lead wires (8), another on four negative lead wires (8) and the fourth on five negative lead wires (8), with a ratio of intensities would be 1 to 2 to 4 to 5.

• 13 negative lead wires (8) implies four current transducers (3). One on a negative lead wire (8), another on three negative lead wires (8), another on four negative lead wires (8) and the fourth on five leads of negative (8), with an intensity ratio would be 1 to 3 to 4 to 5.

• 14 leads of negative (8) implies five current transducers (3). One on a negative (8) lead wire, another on a negative lead wire (8), another on three negative lead wires (8), another on four negative lead wires (8) and the fifth on five lead wires of negative (8), with a ratio of intensities would be 1 to 1 to 3 to 4 to 5.

• 15 negative lead wires (8) involves five current transducers (3). One on a negative (8) lead wire, another on two negative lead wires (8), another on three negative lead wires (8), another on four negative lead wires (8) and the fifth on five lead wires of negative (8), with a ratio of intensities would be 1 to 2 to 3 to 4 to 5.

This makes it possible to calculate the number of current transducers (3) required, depending on the number of negative lead wires (8) to be verified and, thanks to the intensity ratios, the number of required current transducers (3) can be optimized, being able to to determine the lack of up to a negative lead wire (8). In addition, the system (1) is independent of the material and the section of the negative lead wires (8).

Additionally, as the hall effect sensors of the intensity transducers (3) acquire the intensity measurements of each negative (8) conductor cable previously linked and are easily installable on the negative (8) conductor cable, without having to disconnect These negative lead wires (8) for installation. In this way, the current transducers (3) do not affect the normal operation of the return flows to the electrical substation, avoid risks for personnel working in the installation of the device, and are easily installable.

The measurements of these intensity transducers (3) reach a first medium of communication of the control unit (4) through a data bus that links the current (3) and feeder (2) transducers to the first means of the control unit (4). Additionally, the control unit (4) also receives through this data bus the measurements of the ground transducer (10) which is linked to the earth plate (11) of the electrical substation (6).

Additionally, the control unit (4) comprises a memory which in turn comprises instructions for detecting cuts and leakage currents, and a microprocessor linked to said memory. This microprocessor, through the measurements of each hall effect sensor and the instructions for detecting cuts and leakage currents, monitors the status of each of the negative lead wires (8) and detects if a cut has been generated or a leakage current in any of them. When it detects that cut or leak, it generates an alarm to warn the operator through the alert unit (5).

Additionally, thanks to the measurements of the ground transducer (10), the control unit (4) can detect a cut or a leakage current produced by a supply of intensity from an external power source.

Additionally, the control unit (4) comprises a second communication means intended to establish a communication with the alert unit (5) so that it notifies the alerts to the operator that can be found in the electrical substation (6) and / or distance in a control center.

Preferably, the control unit (4) is a control PLC, the first communication means being a first plurality of analog inputs for connecting the current transducers (3) to the PLC, a second plurality of analog inputs for connecting the transducer of feeder (2), and a third plurality of analog inputs to connect the ground transducer (10) to the PLC, the second means of communication is a plurality of digital inputs intended to connect to the alert unit (5). Additionally, the second communication means can be both wired and wireless and therefore the control unit (4) comprises an Ethernet port and / or a WiFi antenna to connect said digital inputs with the alert unit (5).

Preferably, the alert unit (5) comprises a touch screen that allows the operator to interact with the control unit (4) to access the memory and modify the intensity parameters, classify the alarms, perform diagnostics of the electrical installation and obtain information on the measurements of the transducers (2, 3, 10). Additionally, the alert unit (5) comprises a loudspeaker for reproducing a sound alert signal, while the touch screen can reproduce a visual alarm signal.

Claims (14)

1.- System (1) for the detection of cuts in negative lead wires (8) and leakage currents in electrical installations with a plurality of electrical substations (6) of a rail transport network (7), where in turn the electrical substations (6) comprise at least one negative cable (8), at least one positive feeder (9) and one negative well with a ground plate, characterized in that the system (1) comprises: • a first current transducer (3) intended to be linked to at least one of the negative lead wires (8) of at least one of the electrical substations (6), to measure the return current, • a feeder transducer (2) intended to be linked with at least one positive feeder (9) of the electric substation (6), to measure the intensity consumed by the positive feeder (9), • a ground transducer (10) intended to be connected to the earth plate (11) of the negative well of the electric substation (6), to measure the intensity provided by any external power source, • an alert unit (5) comprising a screen and / or a loudspeaker to generate a visual or audible alarm, • at least one control unit (4) comprising: or a first means of communication intended to establish a communication with the intensity transducer, with the feeder transducer (2) and with the ground transducer (10), or a memory which in turn comprises instructions for detecting cuts and leakage currents, or a second means of communication intended to establish a communication with the alert unit (5), or a microprocessor linked to the memory, to the first means of communication, and to the second means of communication to detect cuts and leakage currents in negative (8) conductor cables, by means of the instructions for detecting cuts and leakage currents. the memory, and notify it through the second means of communication to the alert unit (5) so that it notifies an operator through the visual or audible alarm. 2. System (1) according to claim 1, characterized in that the feeder transducer (2) comprises a hall effect transducer with an analog / digital signal converter. 3. System (1) according to claim 1, characterized in that the intensity transducer (3) is a hall effect sensor linked to an analog / digital signal converter. 4. System (1) according to claim 1, characterized in that the ground transducer (10) is a hall effect sensor linked to an analog / digital signal converter. 5. - System (1) according to claim 1, characterized in that it comprises a plurality of intensity transducers (3) comprising the first intensity transducer (3) and a second intensity transducer (3) intended to be linked with a plurality of negative lead wires (8), so that the first current transducer (3) is linked with a single negative lead wire (8) and the second current transducer (3) is linked with up to 3 wire leads negative (8). 6. System (1) according to claim 5, characterized in that it comprises a plurality of intensity transducers (3) comprising the first intensity transducer (3), the second current transducer (3) and a third current transducer (3) intended to be linked with a plurality of negative lead wires (8), so that the first current transducer (3) is linked with a single negative lead wire (8), the second current transducer (3) ) is linked to up to 2 negative lead wires (8) and the third current transducer (3) is linked with up to 5 negative lead wires (8). 7. System (1) according to claim 6, characterized in that it comprises a plurality of intensity transducers (3) comprising the first intensity transducer (3), the second intensity transducer (3), the third intensity transducer (3) and a fourth current transducer (3) intended to be linked with a plurality of negative lead wires (8), so that the first current transducer (3) is linked with a single negative lead wire (8). ), the second transducer of intensity (3) is linked with up to 2 negative lead wires (8), the third current transducer (3) is linked with up to 3 negative lead wires (8), the fourth current transducer (3) is linked with up to 5 negative lead wires (8). 8. - System (1) according to claim 7, characterized in that it comprises a plurality of intensity transducers (3) comprising the first intensity transducer (3), the second intensity transducer (3), the third current transducer (3), the fourth current transducer (3) and a fifth current transducer (3) intended to be linked with a plurality of electric conductor wires. negative (8), so that the first current transducer (3) is linked with a single negative lead wire (8), the second current transducer (3) is linked with up to 2 negative lead wires (8), the third current transducer (3) is linked with up to 3 negative lead wires (8), the fourth current transducer (3) is linked with up to 4 negative lead wires (8) and the fifth current transducer (3) is linked with up to 5 negative lead wires (8). 9. - System (1) according to any one of claims 5 to 8, characterized in that the control unit (4) comprises a first comparator for, by means of the instructions for detecting cuts and leakage currents included in the memory, compare the measurements of each of the current transducers (3) to detect the cut of any one of the negative lead wires (8). 10. - System (1) according to claim 1, characterized in that the control unit (4) comprises a second comparator for, by means of the instructions for detecting cuts and leakage currents included in the memory, to compare the measurement of the transducer of intensity (3) with the measurement of the feeder transducer (2) to detect external leakage currents in the transport network. 11. System (1) according to claim 10, characterized in that, the control unit (4) comprises an intensity monitoring circuit for, by means of the instructions for detecting cuts and leakage currents comprised in the memory, monitoring the intensity measured by the ground transducer (10) and establishing the leakage current of the substation electric (6); and comprises a generator generating circuit alarms to generate the visual or audible alarm when the leakage current is higher than 300A and reproduce it through the warning unit (5). 12. - System (1) according to claim 11, characterized in that the alarm generating circuit is configured to generate a disconnection alarm when the leakage current is greater than 650A and reproduce it through the warning unit (5) for so that the operator disconnects the electrical substation. 13. - System (1) according to claim 1, characterized in that the control unit (4), comprises a third comparator for, by means of the instructions for detecting cuts and leakage currents included in the memory, compare the measurement of the current transducer (3) with the measurement of the feeder transducer (2), to detect leakage currents in the transport network so that the third comparator detects a leakage current when the current measured by the feeder transducer (2) is greater than the current measured by the return current transducer (3). 14. - System (1) according to claim 1, characterized in that the alert unit (5) comprises a touch screen that allows the operator to interact with the control unit (4) to access the memory and modify an intensity parameter for the current transducer, classify the alarms, perform electrical installation diagnostics and obtain information on the measurements of the current transducers (3), feeder transducers (2) and ground transducers (10).