KR20110115707A - The return current ratio measurement system for real time leakage current monitoring on the dc railway system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway, wherein a feeder current measurement for measuring a current flowing through a feeder of a positive electrode through a direct current CT (current transformer) connected to a positive feeder Module 100; Feedback current measuring module connected to the cable connecting the rail and the negative electrode, measuring the return current flowing through the cable, measuring the return current and rail potential returned from the ground network, and measuring the return current returned from the leakage current collecting network ( 200); A rail measuring current and voltage of each line flowing from the substation and flowing into the rail, and measuring the magnitude of the four rail currents flowing through each rail through the current sensors provided in four parts of the left and right and up and down lines entering the substation. Current measurement module 300; And the amount of current flowing through the feeder of the positive electrode measured by the feeder current measuring module 100, the amount of current of the rail measured by the feedback current measuring module 200, the amount of current of the ground network and the collecting network, and the amount of rail current measuring module ( A remote data processing module 400 for storing and managing current and voltage amounts for each line flowing to the rail measured by 300 and analyzing and monitoring respective data; .

Description

Return current ratio measurement system for real-time leakage current prediction of DC electric railway {THE RETURN CURRENT RATIO MEASUREMENT SYSTEM FOR REAL TIME LEAKAGE CURRENT MONITORING ON THE DC RAILWAY SYSTEM}

The present invention relates to a feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway, and more particularly, leakage by using each feedback current ratio flowing through the rail, leakage current collecting network and ground network returned to the substation. The present invention relates to a technique for predicting current generation and magnitude.

In DC electric railways, part of the operating current returned to the substation through the running rails is leaked to the ground when the electric vehicle travels, and this leakage current causes not only the railway facilities but also metals buried underground.

Therefore, in order to reduce the current leaking from the rail, most of the feedback rails are insulated from the ground in the DC electric railway. However, since the leakage current generated between these rails and the ground cannot be measured directly, the operating current, the distance between the substations, the conductivity of the track and other feedback circuits, the resistance of the rail, and the cross bond affecting the generation of such leakage current The intervals between and the like have been considered since the design of DC electric railways.

However, due to the change in the running current according to the driving conditions and various influence factors due to the aging of the system, the insulation resistance value between the rail and the ground is changed, and the leakage current caused by the change of the insulation resistance increases the railroad. As this affects the spread of metal structures and underground metal buried materials, it is necessary to continuously monitor the change of the leakage current to determine the stability of the insulation between the rail and the ground.

In DC electric railways, it is difficult to directly measure the leakage current returned from the rail. Therefore, it is generally estimated through the change of the insulation resistance of the feedback circuit to the ground or the magnitude of the rail potential generated by the train operation.

When the conductivity of the rail per unit length changes significantly, the rail potential changes along the track. Therefore, after setting a reference value that satisfies the acceptance criteria for leakage current in the construction of the system, it is possible to predict the change of the leakage current in real time through the difference between the rail potential value and the reference value according to the train operation.

The change of the rail potential along the track indicates that there is a defect in the conductivity per unit length due to the change in the conductivity of the feedback circuit, the poor connection between the feedback circuit and the ground, and the contamination of the rail fastening device. That means you can have it.

As shown in FIG. 1, in the rail potential monitoring technique, which is a technique for predicting the magnitude of leakage current in real time, a communication-based voltage sensor for measuring the potential between the rail and the ground is largely used as a rail potential such as a substation and a station. Install rails at critical points for measurement.

In general, the distance between the sensors is installed at intervals of 1 to 3 km, and the rail potential at each point is evaluated by the central processing system for changes in leakage current, and the data is sent to a place where command or monitoring and control is required through a modem or the Internet. It consists of a system that can be transmitted. Since the magnitude of the rail potential is always changed according to the train operation pattern, the rail potential value of the 24-hour average time is used in order not to be affected by the difference in daily traffic volume. The change in the average rail potential may cause a change in the rail-to-earth conductivity and can detect a change in the leakage current.

In this technique, it is possible to determine the degradation of the insulation between the ground and the rail occurring between the sensor and the sensor by changing the magnitude of the voltage measured by the voltage sensor, which can greatly help maintenance.

However, the conventional rail potential monitoring technique as described above cannot directly measure the leakage current from the rail, and thus indirectly measures the leakage current by using the potential difference between the rail and the ground. However, since the magnitude of the rail potential changes from time to time depending on the pattern of the train operation, it is difficult to calculate the limit value.

In addition, since most of the tracks are made of concrete, it is difficult to construct an additional grounding network for catching the reference value of the earth potential in existing routes, and there is a disadvantage in that a communication network must be established in a long distance section. .

Therefore, while the existing method is suitable for initial installation and operation on a new line, it is difficult to install and to set an allowance value in the existing operation section.

An object of the present invention is to wirelessly measure the magnitude of the voltage between the ground and the rail to monitor the magnitude change of the leakage current in real time, and in the substation, the current ratio returned to the negative electrode through the rail, leakage current collecting network and ground network The purpose is to provide a system that can monitor the insulation between rail and earth in real time by comparing the voltage magnitude and current ratio in the dry state.

The feedback current ratio measurement system for real-time leakage current prediction of the DC electric railway of the present invention for achieving the technical problem, the current flowing through the feeder of the positive electrode through a direct current CT (current transformer) connected to the feeder of the positive electrode A feeder current measuring module 100 for measuring; Feedback current measuring module connected to the cable connecting the rail and the negative electrode, measuring the return current flowing through the cable, measuring the return current and rail potential returned from the ground network, and measuring the return current returned from the leakage current collecting network ( 200); A rail measuring current and voltage of each line flowing from the substation and flowing into the rail, and measuring the magnitude of the four rail currents flowing through each rail through the current sensors provided in four parts of the left and right and up and down lines entering the substation. Current measurement module 300; And the amount of current flowing through the feeder of the positive electrode measured by the feeder current measuring module 100, the amount of current of the rail measured by the feedback current measuring module 200, the amount of current of the ground network and the collecting network, and the amount of rail current measuring module ( A remote data processing module 400 for storing and managing current and voltage amounts for each line flowing to the rail measured by 300 and analyzing and monitoring respective data; .

In addition, the feedback current measuring module 200 is connected to the negative electrode of the rail and collects the current returned from a plurality of cables provided through a pre-installed current sensor rail current measuring unit for calculating the current amount of the rail returned through the rail 210; A ground / collection network measuring unit 220 for calculating the amount of current in the ground network and the amount of current in the leakage current collecting network through a diode connected and provided between the ground network, the leakage current collecting network, and the negative electrode; And the rail current measuring unit 210 receives the current amount of the rail, and the ground / collection network measuring unit 220 receives the current amount of the ground network and the leakage current collecting network current amount, respectively. A feedback current ratio calculator 230 for calculating a feedback current ratio with respect to an amount of current in the network; It includes.

In addition, the grounding and collecting network measuring unit 220 is composed of a diode between the grounding network, the leakage current collecting network and the negative electrode, thereby preventing current from flowing from the rail to the ground or leakage current collecting network. It is characterized by performing a function.

In addition, the remote data processing module 400 derives the sum of the current of the positive electrode bus and the current of the negative electrode bus from the amount of current flowing through the feeder of the positive electrode through [Equation 1], and flows from the negative electrode bus through [Equation 2]. The current distribution ratio of the current amount of the rail, the current amount of the ground network and the current amount of the collecting network is derived, and the current magnitude, current ratio and voltage magnitude of the rails flowing through the four rails are represented by Equation 3 below.

[Equation 1]

Sum of current of positive bus

Sum of current of negative bus

&Quot; (2) "

&Quot; (3) "

Then, the remote data processing module 400, the current distribution ratio of the derived current of the positive bus and the current of the negative bus, the current amount of the rail flowing from the negative bus, the current of the ground network and the current of the collecting network, and four rails It is characterized by plotting the current magnitude, current ratio and voltage magnitude of the rail flowing in the daily, weekly and monthly averages, respectively.

According to the present invention as described above, by measuring the current flowing back through the leakage current collecting network and the ground network in real time by connecting the current and the diode returned from the operating rail of the existing substation and the rail and the ground through the change of the current ratio flowing By monitoring the degree of insulation between the real-time, there is an effect that can be applied not only to the new line but also to the existing DC power supply system.

In addition, according to the present invention, the leakage current is predicted through the rail potential in the conventional method, and the magnitude of the leakage current cannot be predicted by comparing the magnitude of the return current. There is.

1 is a block diagram showing a prediction system through a conventional real-time rail potential monitoring.
Figure 2 is a block diagram showing a feedback current ratio measurement system for real-time leakage current prediction of DC electric railway according to the present invention.
3 is a block diagram illustrating a feedback current ratio measurement system for real-time leakage current prediction of DC electric railway according to the present invention.
Figure 4 is a block diagram showing a feedback current measuring module of the feedback current ratio measurement system for real-time leakage current prediction of DC electric railway according to the present invention.
5 is a configuration diagram illustrating a feedback current measuring module of a feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway according to the present invention.
Figure 6 is a block diagram showing a rail current measurement module of the feedback current ratio measurement system for real-time leakage current prediction of DC electric railway according to the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It should be interpreted in terms of meaning and concept. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

As shown in FIGS. 2 and 3, the feedback current ratio measurement system S for real-time leakage current prediction of a DC electric railway according to the present invention includes a feeder current measurement module 100, a feedback current measurement module 200, Rail current measuring module 300 and remote data processing module 400 is configured to include.

Referring to FIGS. 2 and 3, the feeder current measuring module 100 of the feedback current ratio measuring system S for real-time leakage current prediction of a DC electric rail according to the present invention is as follows.

The feeder current measuring module 100 measures the current flowing through the feeder of the positive electrode through a direct current CT (current transformer) connected to the feeder (feeding line or feeder line) of the positive electrode.

Referring to FIGS. 2, 4 and 5, the feedback current measuring module 200 of the feedback current ratio measurement system S for real-time leakage current prediction of the DC electric rail according to the present invention is as follows.

The feedback current measuring module 200 is connected to a cable connecting the running rail and the negative electrode to measure the return current flowing through the cable, measure the return current and rail potential returned from the ground network, and return from the leakage current collecting network. The current is measured by a rail current measuring unit 210, a ground and collecting network measuring unit 220, and a feedback current ratio calculating unit 230.

Specifically, the rail current measuring unit 210 calculates the amount of current of the rail returned through the rail by collecting the current returned from a plurality of cables connected to the negative electrode of the rail through a pre-installed current sensor.

In addition, the ground / collection network measuring unit 220 calculates the amount of current in the ground network and the amount of current in the leakage current collecting network through a diode connected and provided between the ground network, the leakage current collecting network, and the negative electrode.

Here, the grounding and collecting network measuring unit 220 is composed of a diode between the grounding network, the leakage current collecting network and the negative electrode, and thus prevents current from flowing from the rail to the ground or leakage current collecting network. Will be performed.

The feedback current ratio calculating unit 230 receives the current amount of the rail from the rail current measuring unit 210 and the current amount of the ground network and the current amount of the leakage current collecting network from the ground and collecting network measuring unit 220. The return current ratios are calculated for the rail current, the ground network current, and the collection network current, respectively.

Referring to FIGS. 2 and 6, the rail current measurement module 300 of the feedback current ratio measurement system S for real-time leakage current prediction of a DC electric railway according to the present invention will be described as follows.

Rail current measuring module 300 measures the current and voltage for each line flowing from the substation flowing to the rail, the four flowing through each rail through the current sensor provided in the left and right, up and down four lines to the substation By comparing the magnitudes of the two rail currents, we predict the period of aging isolation.

At this time, the current line must measure the current flowing through the rail, so the voltage drop type such as through-hole type or direct current shunt is impossible, and the rail contact type measures the amount of induction in the current. It is jointly connected to the ground network to measure the voltage level between the rail and the ground.

And, the remote data processing module 400 is the amount of current flowing through the feeder of the positive electrode measured by the feeder current measuring module 100, the amount of current of the rail measured by the feedback current measuring module 200, the ground network current and the collecting network It stores and manages the amount of current and the amount of current and voltage for each line flowing to the rail measured by the rail current measurement module 300, and analyzes each data to provide monitoring.

In detail, the data analysis of the remote data processing module 400 may derive the sum of the current of the positive electrode bus and the current of the negative electrode bus from the amount of current flowing through the feeder of the positive electrode through [Equation 1], and through [Equation 2]. The current distribution ratio of the current amount of the rail, the current amount of the ground network, and the current amount of the collecting network flowing from the negative electrode bus line is derived.

[Equation 1]

Sum of current of positive bus

Sum of current of negative bus

&Quot; (2) "

&Quot; (3) "

In addition, the remote data processing module 400 includes the current sum of the current of the positive electrode bus and the current of the negative electrode bus, the current distribution ratio of the current amount of the rail flowing from the negative electrode bus, the current amount of the ground network and the current amount of the collecting network, and the four rails. The current magnitude, current ratio, and voltage magnitude of the flowing rails are plotted into daily, weekly, and monthly averages, respectively.

As described above and described with reference to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as described above, it is a deviation from the scope of the technical idea It will be understood by those skilled in the art that many modifications and variations can be made to the invention without departing from the scope of the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

S: Feedback current ratio measurement system for real-time leakage current prediction of DC electric railway
100: feeder current measurement module 200: feedback current measurement module
210: rail current measuring unit 220: ground, collecting network measuring unit
230: feedback current ratio calculation unit 300: rail current measurement module
400: remote data processing module

Claims (5)

In the feedback current ratio measurement system for real-time leakage current prediction of DC electric railway,
A feeder current measuring module 100 for measuring a current flowing through the feeder of the positive electrode through a direct current CT (current transformer) connected to the feeder of the positive electrode;
Feedback current measuring module connected to the cable connecting the rail and the negative electrode, measuring the return current flowing through the cable, measuring the return current and rail potential returned from the ground network, and measuring the return current returned from the leakage current collecting network ( 200);
A rail measuring current and voltage of each line flowing from the substation and flowing into the rail, and measuring the magnitude of the four rail currents flowing through each rail through the current sensors provided in four parts of the left and right and up and down lines entering the substation. Current measurement module 300; And
The amount of current flowing through the feeder of the positive electrode measured by the feeder current measuring module 100, the amount of current of the rail measured by the feedback current measuring module 200, the amount of current of the ground network and the collecting network, and the measurement of the rail current A remote data processing module 400 for storing and managing current and voltage amounts for each line flowing to the rail measured by the module 300, and analyzing and monitoring respective data; Feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway comprising a. The method of claim 1,
The feedback current measuring module 200,
A rail current measurement unit 210 configured to calculate a current amount of the rail returned through the rail by collecting current returned from a plurality of cables connected to the negative electrode of the rail through a pre-installed current sensor;
A ground / collection network measuring unit 220 for calculating the amount of current in the ground network and the amount of current in the leakage current collecting network through a diode connected and provided between the ground network, the leakage current collecting network, and the negative electrode; And
The rail current measuring unit 210 receives the current amount of the rail, and the ground and collecting network measuring unit 220 receives the current amount of the ground network and the leakage current collecting network current amount, respectively, the current amount of the rail, the ground network current amount, and A feedback current ratio calculator 230 for calculating a feedback current ratio with respect to the current amount of the collecting network; Feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway comprising a. The method of claim 2,
The ground and collection network measuring unit 220,
It consists of a diode between the ground network, the leakage current collecting network and the negative electrode, thereby preventing the current from flowing from the rail to the ground or leakage current collecting network, thereby performing the same function as the selective distributor. Feedback current measurement system for estimating leakage current. The method of claim 1,
The remote data processing module 400,
[Equation 1] derives the sum of the current of the positive electrode bus and the current of the negative electrode bus from the amount of current flowing in the feeder of the positive electrode, and the current amount of the rail, the current of the ground network and the collection network that flows from the negative bus through [Equation 2] Derivation current for real-time leakage current prediction of DC electric railway, which derives the current distribution ratio of the amount of current and derives the current magnitude, current ratio, and voltage magnitude of the rail flowing through four rails through [Equation 3] Non measuring system.
[Equation 1]
Sum of current of positive bus

Sum of current of negative bus

&Quot; (2) "

&Quot; (3) "

The method of claim 1,
The remote data processing module 400,
The sum of the currents of the positive and negative buses, the current distribution ratios of the currents of the rails, the currents of the ground network and the currents of the collecting network, and the current magnitude, current ratio and voltage of the rails flowing through the four rails. A feedback current ratio measurement system for real-time leakage current prediction of a DC electric railway, characterized in that the magnitude is plotted into a daily average, a week average, and a monthly average, respectively.

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