KR20200029870A - Relay apparatus and system including the same - Google Patents

Abstract

According to an embodiment of the present invention, disclosed is a relay apparatus comprising: a first reception unit for receiving a first current signal and a first voltage signal on a first node adjacent to a first substation on a power line arranged between the first substation and a second substation adjacent to the first substation; an output unit for outputting a first signal when the first current signal is larger than a predetermined value; a detection unit for detecting a first direction which is a direction of the first current signal on the first node by using a phase difference between the first current signal and the first voltage signal; a second reception unit for receiving a second direction which is a direction of a second current signal on a second node adjacent to the second substation; and a determination unit for determining that the power line is defective when the first signal is outputted and the first direction and the second direction are the same, and for determining that the power line is normal when the first signal is outputted and the first direction and the second direction are different from each other.

Description

Relay device and relay system including the same {RELAY APPARATUS AND SYSTEM INCLUDING THE SAME}

Embodiments relate to a relay device and a relay system comprising the same.

In the case of a catenary accident in a DC power supply system that is fed in parallel, the contact car step electricity used in urban railroads is a device used to cut off both side breakers at the same time to cut off the power supply to the accident point. However, since the operation of the tram can be stopped when a breaker in the substation is operated due to a malfunction, it is also a device that requires considerable operation reliability.

Currently, cases of operation due to malfunction are often reported, and the cause is considered to be due to a change in the resistance value of the display line due to fine dust, oil, and vibration between the contacts. It is difficult to completely block the effects that may cause a malfunction due to the surrounding environment. Therefore, there is a need for a liaison step-by-step method that can guarantee maximum reliability even under these adverse conditions.

At this time, the breaker operation of the substation is determined according to whether a failure has occurred in the line between the substations or in a line other than the substation. However, there are limitations in that it is difficult to judge where the failure has occurred.

The embodiment provides a relay device that accurately cuts off the electrical connection of the breaker.

It also provides a relay device that provides system separation for a faulty line.

In addition, a relay device for minimizing the blackout section is provided.

The problem to be solved in the embodiment is not limited to this, and it will be said that the object or effect that can be grasped from the solution means or the embodiment of the problem described below is also included.

The relay device according to the embodiment includes a first current signal and a first voltage signal on a first node adjacent to the first substation on a power line disposed between a first substation and a second substation adjacent to the first substation. 1 receiver; An output unit configured to output a first signal when the first current signal is greater than a preset value; A detector configured to detect a first direction that is a direction of a first current signal at the first node by using a phase difference between the first current signal and the first voltage signal; A second receiver configured to receive a second direction that is a direction of a second current signal on a second node adjacent to the second substation; And when the first signal is output and the first direction and the second direction are the same, the power line is determined as a failure, and when the first signal is output and the first direction and the second direction are different. And a determining unit determining the power line as normal.

When the determination unit determines that it is a failure, it may include a control unit for outputting a control signal to cut off the electrical connection of the first circuit breaker connected to the first node.

The control unit may output a control signal that maintains the electrical connection of the second circuit breaker connected to the second node when the determination unit determines that it is normal.

The first node and the second node may be spaced apart.

The detection unit may detect the first direction in the forward direction when the phase difference between the first current signal and the first voltage signal is in the first range, and the first direction in the reverse direction in the second range.

The first range may be -90 degrees to 90 degrees.

The second range may be 90 degrees to -90 degrees.

It may further include a; transmitting unit for transmitting the first direction to the outside.

The transmitting unit may transmit a control signal maintaining an electrical connection output from the control unit to the outside.

The power line may be electrically connected to the load unit.

According to an embodiment, the relay device may be implemented in a form of accurately blocking the electrical connection of the breaker.

It is also possible to fabricate relay devices that provide system separation for faulty lines.

Further, it is possible to manufacture a relay device that minimizes the blackout section.

The various and beneficial advantages and effects of the present invention are not limited to the above, and will be more readily understood in the course of describing specific embodiments of the present invention.

1 is a conceptual diagram showing a relay system including a relay device according to an embodiment,
2 is a block diagram of a relay device according to an embodiment,
3 is a view for explaining the operation of the relay device according to the embodiment,
4 to 5 are views for explaining the operation of the relay device on a plurality of power lines connected to each other,
It is a figure explaining operation | movement of other relay devices.

The present invention can be applied to various changes and can have various embodiments, and specific embodiments will be illustrated and described in the drawings. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms including ordinal numbers such as second and first may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from other components. For example, the second component may be referred to as a first component without departing from the scope of the present invention, and similarly, the first component may also be referred to as a second component. The term and / or includes a combination of a plurality of related described items or any one of a plurality of related described items.

When an element is said to be "connected" or "connected" to another component, it is understood that other components may be directly connected to or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that no other component exists in the middle.

The terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "include" or "have" are intended to indicate the presence of features, numbers, steps, actions, components, parts or combinations thereof described herein, one or more other features. It should be understood that the existence or addition possibilities of fields or numbers, steps, operations, components, parts or combinations thereof are not excluded in advance.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains. Terms such as those defined in a commonly used dictionary should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings, but the same or corresponding components are assigned the same reference numbers regardless of reference numerals, and overlapping descriptions thereof will be omitted.

1 is a conceptual diagram showing a relay system including a relay device according to an embodiment, and FIG. 2 is a block diagram of a relay device according to an embodiment.

1 and 2, the relay system 1 according to the embodiment includes a power supply unit (G1, G2), a substation 10, a power line 20, a relay device 30, a breaker 40 You can.

First, the power supply units G1 and G2 generate electricity to supply power to a substation or the like. That is, the power supply units G1 and G2 may be power supply systems that provide high-voltage and ultra-high-voltage power. For example, the power unit may include a power plant, distributed power, and the like, but is not limited to this type.

In addition, since the power supply units G1 and G2 provide power to the substation, it can be connected to the substation. In addition, a plurality of power supply units may be provided. For example, the power units G1 and G2 may include a first power unit G1 and a second power unit G2.

The substation 10 may receive power from the power supply units G1 and G2 to convert voltage and the like of power. Specifically, the substation 10 may be provided as a power line by raising or lowering the power supplied from the power supply units (G1, G2). That is, the substation 10 may provide the power line by increasing or decreasing the voltage level. In addition, the substation 10 may receive power from a three-phase AC high-voltage system. For example, the substation 10 may include a steel substation, a water receiving substation, a coastal substation, a rolling substation, and the like, but is not limited to this type.

Also, a plurality of substations 10 may be provided. For example, the substation 10 may include a first substation 10a, a second substation 10b, a third substation 10c, and a fourth substation 10d. However, it is not limited to this number.

The power line 20 may be electrically connected to a plurality of substations 10. That is, the power line may be an electric line that supplies power. And the power line 20 may include a transmission line or a distribution line.

And the power line 20 is between the power supply (G1, G2), between the substation 10, between the power supply (G1, G2) and the substation 10, the substation 10 and the load connected to the consumer (L1 to L3 to be described later) ). For example, the power line 20 may be disposed between a plurality of substations 10, and the first power line 20a and the second substation (1) disposed between the first substation 10a and the second substation 10b. It may include a second power line 20b disposed between 10b) and the third substation 10c, and a third power line 20c disposed between the third substation 10c and the fourth substation 10d. . However, it is not limited to this number.

And the power line 20 may be connected to each substation 10 in the form of an annular line. Accordingly, a path through which power generated by the power units G1 and G2 flows may be changed according to the amount of power required by the load unit. That is, as the amount of power required by the load portion increases or decreases, the power may flow in a clockwise or counterclockwise direction in the form of an annular line.

The relay device 30 may be disposed on the power line 20 and connected to the power line 20. In addition, a plurality of relay devices 30 may be provided. For example, a plurality of relay devices 30 may be arranged on one power line 20. More specifically, the first relay device 30a and the second relay device 30b may be disposed on the first power line 20a. At this time, the first relay device 30a may be disposed adjacent to the first substation 10a, and the second relay device 30b may be disposed adjacent to the second substation 10b. In addition, the first relay device 30a and the second relay device 30b may be spaced apart from each other.

Further, the first relay device 30a is a current signal and a voltage signal (hereinafter, a first current signal and a first voltage) of a first node (not shown) adjacent to the first substation 10a on the first power line 20a. Signal). In addition, the first relay device 30a may detect whether the current is overcurrent and the direction of the current (hereinafter, the first direction) using the first current signal and the first voltage signal of the first node, and the second relay device 30b ), It is possible to determine whether a failure has occurred on the first power line 20a by receiving the direction of the current. In addition, the first relay device 30a outputs a control signal (for example, a breaker trip signal) that blocks a breaker (the first breaker described later) connected to the first relay device 30a and transmits it to the first breaker. You can. For example, when the control signal is transmitted to the first breaker, the first breaker may cut off the electrical connection of the first power line 20a.

And the second relay device 30b is the current signal and voltage of the second node (not shown) adjacent to the second substation 10b on the first power line 20a corresponding to the first relay device 30a described above. A signal (hereinafter referred to as a second current signal and a second voltage signal) is received, and whether it is overcurrent, the direction of the current (hereinafter referred to as the second direction) and the first power supply line in the first direction of the first relay device 30a ( It is possible to determine whether a failure has occurred in 20a). In addition, the second relay device 30b may output a control signal that blocks a circuit breaker (second circuit breaker described later) connected to the second relay device 30b and transmits it to the second circuit breaker. For example, when the control signal is transmitted to the second circuit breaker, the second circuit breaker may cut off the electrical connection of the first power line 20a.

That is, the first relay device 30a and the second relay device 30b are spaced apart on the first power line 20a to determine whether or not the overcurrents at different points (first node, second node) are overcurrent and the direction of the current. Can be detected. In addition, after receiving the second direction from the second relay device 30b, the first relay device 30a determines whether the first power line 20a has failed and controls the blocking of the first breaker when the fault is determined. can do. Similarly, after receiving the first direction from the first relay device 30a, the second relay device 30b determines whether the first power line 20a has failed and controls the blocking of the second breaker when determining the fault. You can.

Accordingly, the first relay device 30a and the second relay device 30b use the same power supply line, that is, the first power supply line using the current direction or the like of overcurrent at different points on the first power supply line 20a. 20a) can be judged. In addition, when the first power line 20a is broken, the electrical connection of the first power line 20a is cut off, so that the fault line can be easily separated.

The relay device 30 according to the embodiment includes a first reception unit 31, an output unit 32, a detection unit 33, a second reception unit 34, a determination unit 35, a control unit 36, and a transmission unit 37 It may include. Hereinafter, the relay device 30 will be described based on the operation of the first relay device 30a of FIG. 1, but the operations described below correspond to operations of relay devices other than the first relay device.

First, the first receiver 31 may receive a current signal and a voltage signal of a node disposed adjacent to one substation between substations connected by a power line (corresponding to the first power line). Specifically, the first receiver 31 receives the first current signal and the first voltage signal on the first node adjacent to the first substation on a power line disposed between the first substation and the second substation adjacent to the first substation. I can receive it.

The output unit 32 may compare the first current signal with a preset value (hereinafter, a threshold value) and output the first signal when determining the overcurrent. Here, the preset value may be a maximum value of current that can be obtained when the power line is not a fault. In this case, the maximum value of the current may be the magnitude of the current flowing through the power supply line at the minimum load, but is not limited thereto and may be set by a user.

The detector 33 may detect the first direction, which is the direction of the first current signal, at the first node using the phase difference between the first current signal and the first voltage signal of the first receiver 31. At this time, the detector 33 may detect the first direction in the forward direction when the phase difference between the first current signal and the first voltage signal is the first range based on the first voltage signal. Also, the detector 33 may detect the first direction in the reverse direction when the phase difference between the first current signal and the first voltage signal is the second range based on the first voltage signal. Here, the first range is -90 degrees to 90 degrees, and the second range is 90 degrees to -90 degrees (or 90 degrees to 270 degrees). The forward direction is the direction from the substation adjacent to the node toward the power line, and the reverse direction is the direction from the power line toward the substation adjacent to the node.

The second receiving unit 34 may receive the second direction, which is the direction of the second current signal of the second node disposed on the adjacent substation on the same power line. More specifically, the second receiver 34 may receive the second direction, which is the direction of the second current signal of the second node, from the relay device disposed adjacent to the second substation.

The determination unit 35 may determine whether or not the first signal is output, and compare the first direction and the second direction with each other to determine whether the power line has failed. Specifically, the determination unit 35 may determine the power line as a failure when the first signal is output and the first direction and the second direction are the same. Also, the determination unit 35 may determine the power line as normal when the first signal is output and the first direction and the second direction are different.

That is, the determination unit 35 does not determine that the first power line is defective even if the first direction is forward and the first signal is output (determined as overcurrent). However, when the first signal is output, the determination unit 35 may determine that the failure itself has occurred. That is, the determination unit 35 determines whether the failure occurs in the first power line (internal failure) or in a power line other than the first power line (external failure) in the second direction and the first direction. It can be done by comparison.

The control unit 36 may output a control signal that cuts off the electrical connection to the first circuit breaker connected to the first node when the determination unit 35 determines that the first power line 20a is a failure. That is, the control unit 36 outputs a control signal that cuts off the electrical connection of the first breaker 40a disposed adjacent to the measurement position of the first current signal and the second current signal received from the first receiving unit 31. You can. For example, the control unit 36 may output a trip signal that blocks the electrical connection of the first breaker 40a.

In addition, when determining that the first power line 20a is normal by the determination unit 35, the control unit 36 may output a control signal that maintains an electrical connection to a second circuit breaker connected to the second node. That is, when the first direction and the second direction are different, the control unit 36 determines that it is an external failure and outputs a control signal maintained by the second circuit breaker 40b disposed adjacent to the second relay device without blocking electrical connection. can do.

In addition, the control unit 36 includes application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), processors, and controllers. At least one of (controllers), microcontrollers, microprocessors, and electrical units for performing other functions may be used, but is not limited to this type.

The transmitter 37 may transmit the first direction to the outside. For example, the first relay device 30a may transmit the first signal detected by the detection unit 33 to the second relay device 30b. That is, the second relay device 30b can also determine whether the first power supply line 20a is faulty, and prevent the first relay device 30a from blocking the first breaker in the event of an external fault. In addition, the transmitting unit 37 may transmit a control signal that blocks the electrical connection output from the control unit 36 to the first breaker, and transmits a control signal that maintains the electrical connection to the second relay device 30b or the second breaker. (40b).

The transmission unit 37 is optical communication, wired LAN (Local Area Network; LAN), USB (Universal Serial Bus), Ethernet (Ethernet), power line communication (Power Line Communication; PLC), wireless LAN (Wireless LAN), code division Code Division Multiple Access (CDMA), Time Division Multiple Access (TDMA), Frequency Division Multiple Access (FDMA), Wireless Broadband Internet (WiBro), Long Term Evolution (LTE) ), High Speed Downlink Packet Access (HSDPA), Wideband CDMA (WCDMA), Ultra WideBand (UWB), Ubiquitous Sensor Network (USN), RFID (Radio Frequency IDentification), infrared communication (Infrared Data Association; IrDA), NFC (Near Field Communication), ZigBee any one of the can be made. The above communication method can be applied to the first receiver and the second receiver.

3 is a view for explaining the operation of the relay device according to an embodiment, FIGS. 4 to 5 are views for explaining the operation of the relay device on a plurality of power lines connected to each other, and FIG. 6 is for operation of other relay devices. It is an explanatory drawing.

First, referring to FIG. 3, the first power supply unit G1 is connected to the first substation 10a, and the first substation 10a is electrically connected to the second substation 20b through the first power line 20a. Can be connected. In addition, the first power supply unit G1 may provide power to the first substation 10a. At this time, the power line 20a is disposed between the first substation 10a and the second substation 10b, but in the drawings below, the first breaker 40a and the second breaker 40b are specified as protection sections. Shows. However, the present invention is not limited thereto, and the power line 20a includes all or some areas between the first substation 10a and the second substation 10b.

In addition, the second power supply unit G2 is connected to the second substation 10b to provide power to the second substation 10b.

In addition, the first substation 10a may be electrically connected to the first load unit L1 through the first power line 20a. Accordingly, power supplied by the first power supply unit G1 may be provided to the first load unit L1.

In addition, the second substation 10b may be electrically connected to the second load unit L2 through the first power line 20a. Accordingly, power supplied by the second power supply unit G2 may be provided to the second load unit L2.

In addition, the first power supply unit G1 may produce the same or different power from the second power supply unit G2. For example, the first power supply unit G1 may produce the same power as the second power supply unit G2. In this case, the load power of the first load part L1 is smaller than the load power of the second load part L2, so that the current in the first power line L2 is the first substation 10a to the second substation 10b. Can flow toward

Conversely, when the load power of the first load part L1 is greater than the load power of the second load part L2, the current in the first power line L2 is the second substation 10b to the first substation 10a. Can flow toward However, hereinafter, it will be described as a case where the load power of the first load unit L1 is smaller than the load power of the second load unit L2.

At this time, the first relay device 30a determines the overcurrent using the first current signal I1 and the first voltage signal V1 measured at the first node N1, and the first direction is the forward direction or the reverse direction. Cognitive detection. Specifically, the first relay device 30a may output a first signal by comparing the first current signal I1 with a threshold value Ith. Since the first power line 20a is normal and the lines other than the first power line 20a are normal, the magnitude of the first current signal I1 may be smaller than the threshold value Ith.

In addition, the first relay device 30a has a value within a first range in which the phase difference θ1 of the first current signal I1 is greater than -90 ° and less than 90 ° based on the first voltage signal V1 on the X-axis. You can. That is, since the phase difference θ1 of the first current signal I1 based on the first voltage signal V1 in the vector diagram is located in the first and second quadrants of the first relay device 30a, the first direction is forward. I can judge.

However, unlike this, when the phase difference θ1 of the first current signal I1 based on the first voltage signal V1 has a value within a second range greater than 90 ° and less than -90 °, the first direction is reversed. You can judge. That is, in the reverse direction, the phase difference θ1 of the first current signal I1 based on the first voltage signal V1 may be located in the second and third quadrants of the vector diagram.

Similarly, the second relay device 30b may determine the overcurrent using the second current signal I2 and the second voltage signal V2, and detect whether the second direction is the forward direction or the reverse direction. Specifically, the second relay device 30b may output the first signal by comparing the second current signal I2 with a threshold value Ith. Since the first power line 20a is normal and the lines other than the first power line 20a are normal, the magnitude of the second current signal I2 may be smaller than the threshold value Ith.

In addition, the second relay device 30b may determine the second direction in the reverse direction because the phase difference θ1 of the first current signal I1 is within the second range based on the first voltage signal V1 of the X-axis. .

At this time, the first relay device 30a may receive information in the second direction from the second relay device 30b. However, as described above, since the first signal is not output to the first relay device 30a, the first power supply line 20a may be determined as normal. In addition, the first relay device 30a may output a control signal that maintains the electrical connection of the first breaker 40a through the control unit.

The second relay device 30b may also receive information in the first direction from the first relay device 30a corresponding to the operation of the first relay device 30a. However, since the second relay device 30b does not output the first signal, it determines the first power line 20a as normal and outputs a control signal that maintains the electrical connection of the second breaker 40b through the control unit. You can.

Referring to FIG. 4, when the first power supply line 20a has a failure, the first relay device 30a to the fourth relay device 30d may have respective first current signals I1 to fourth current signals ( I4) may be greater than the threshold value Ith.

In addition, the first relay device 30a and the second relay device 30b may have a vector having the same shape as the current signal and the voltage signal. At this time, in the first relay device 30a and the second relay device 30b, the first current signal I1 and the second current signal I2 may be greater than a threshold value. That is, the first relay device 30a and the second relay device 30b may be determined as overcurrent. Also, both the first direction and the second direction may be forward. Accordingly, it is determined that the first relay device 30a and the second relay device 30b have failed on the line.

At this time, the first relay device 30a may receive a second direction from the second relay device 30b and compare whether it is the same as the first direction. At this time, since the first direction and the second direction are the same, the first relay device 30a determines that it is an internal failure and outputs a control signal to cut off the electrical connection of the first breaker 40a, and the first breaker 40a ). Also, the first relay device 30a may transmit information about the first direction to the second relay device 30b. (S1)

In addition, the third relay device 30c may output the first signal because the third current signal I3 is greater than the threshold value Ith. Further, the fourth relay device 30d may output the first signal because the fourth current signal I4 is greater than the threshold value Ith. That is, the third relay device 30c and the fourth relay device 30d may be determined as overcurrent.

However, since the third relay device 30c has the phase difference θ3 in the second range, the third node N3 reverses the direction of the third current signal (hereinafter referred to as the third direction) in the third substation (second substation). Direction toward the substation). In addition, the fourth relay device 30d may determine the direction (hereinafter, the fourth direction) of the fourth current signal at the fourth node N4 in the forward direction.

At this time, since the third direction and the fourth direction of the third relay device 30c and the fourth relay device 30d are different, it may be determined that the second power line 20b is normal. However, as the first signal is output, the third relay device 30c and the fourth relay device 30d may be determined to be an external fault (that is, a fault occurs in the first power line 20a) rather than an internal fault. have. Accordingly, the third relay device 30c may output a control signal that maintains the electrical connection of the third breaker 40c. Also, the third relay device 30c may output a control signal that maintains the electrical connection of the fourth breaker 40d and transmit it to the fourth relay device 40d (S2). Accordingly, the fourth relay device 40d generates an error in the process of receiving information on the third direction from the third relay device 40c, so that even if it is determined that the third direction and the fourth direction are the same, the fourth breaker ( 40d) electrical connection. Accordingly, even if the relay device makes a wrong determination about the direction, it can be easily corrected.

Referring to FIG. 5, FIG. 5 is a case where a failure occurs in the second power line 20b unlike FIG. 4. As described above with reference to FIG. 4, when a failure occurs on the line, the first relay device 30a to the fourth relay device 30d each have a threshold of the first current signal I1 to the fourth current signal I4 It may be greater than the value Ith.

However, the third relay device 30c and the fourth relay device 30d may have vectors having the same shape as the current signal and the voltage signal. In addition, the third relay device 30c and the fourth relay device 30d may have the same direction as the third direction and the fourth direction in the forward direction. Accordingly, it is determined that the third relay device 30c and the fourth relay device 30d have failed on the line.

However, the third relay device 30c may receive the fourth direction from the fourth relay device 30d and compare whether it is the same as the third direction. At this time, since the third direction and the fourth direction are the same, the third relay device 30c determines that it is an internal failure and outputs a control signal to cut off the electrical connection of the third circuit breaker 40C, and the control signal to the third It can transmit to the breaker 40c. Further, the third relay device 30c may transmit information about the third direction to the fourth relay device 30d (S2).

Alternatively, the first relay device 30a may output the first signal because the first current signal I1 is greater than the threshold value Ith. Also, the second relay device 30b may output the first signal because the second current signal I2 is greater than the threshold value Ith. That is, the first relay device 30a and the second relay device 30b may be determined as overcurrent.

However, in the first relay device 30a, since the phase difference θ1 is located in the first range, the direction (or first direction) of the first current signal at the first node N1 is forward (or second at the first substation). Direction toward the substation). Also, the second relay device 30b may determine the direction (or the second direction) of the second current signal at the second node N2 in the reverse direction (the direction from the second substation toward the first substation).

At this time, since the first direction and the second direction of the first relay device 30a and the second relay device 30b are different, it may be determined that the first power line 20a is normal. However, as the first signal is output, the first relay device 30a and the second relay device 30b may be determined as an external fault (that is, a fault occurs in the second power line 20b, etc.) rather than an internal fault. have. Accordingly, the first relay device 30a may output a control signal that maintains the electrical connection of the first breaker 40a. Also, the second relay device 30b may output a control signal that maintains the electrical connection of the second breaker 40b and transmit it to the second relay device 40b. Accordingly, an error occurs in the process of receiving information about the first direction from the first relay device 40a by the second relay device 40b, even if it is determined that the first direction and the second direction are the same. 40b). Accordingly, even if the relay device makes a wrong determination about the direction of the current, it can be easily corrected.

Referring to FIG. 6, FIG. 6 is a case where a failure occurs in a line between FIG. 5 and the third load part L3 connected to the third third substation 10c and the third substation 10c.

As described above, when a failure occurs on a line electrically connected to a power line, the first relay device 30a to the fourth relay device 30d are respectively the first current signal I1 to the fourth current signal I4 ) May be greater than the threshold value Ith.

In addition, the first relay device 30a may output the first signal because the first current signal I1 is greater than the threshold value Ith. Also, the second relay device 30b may output the first signal because the second current signal I2 is greater than the threshold value Ith. That is, the first relay device 30a and the second relay device 30b may be determined as overcurrent.

However, in the first relay device 30a, since the phase difference θ1 is located in the first range, the direction (or first direction) of the first current signal at the first node N1 is forward (or second at the first substation). Direction toward the substation). Also, the second relay device 30b may determine the direction (or the second direction) of the second current signal at the second node N2 in the reverse direction (the direction from the second substation toward the first substation).

At this time, since the first direction and the second direction of the first relay device 30a and the second relay device 30b are different, it may be determined that the first power line 20a is normal. However, as the first signal is output, the first relay device 30a and the second relay device 30b may be determined as an external fault (that is, a fault occurs in the second power line 20b, etc.) rather than an internal fault. have. Accordingly, the first relay device 30a may output a control signal that maintains the electrical connection of the first breaker 40a. Also, the second relay device 30b may output a control signal that maintains the electrical connection of the second breaker 40b and transmit it to the second relay device 40b. Accordingly, an error occurs in the process of receiving information about the first direction from the first relay device 40a by the second relay device 40b, even if it is determined that the first direction and the second direction are the same. 40b). Accordingly, even if the relay device makes a wrong determination about the direction of the current, it can be easily corrected.

In addition, the third relay device 30c may output the first signal because the third current signal I3 is greater than the threshold value Ith. Further, the fourth relay device 30d may output the first signal because the fourth current signal I4 is greater than the threshold value Ith. That is, the third relay device 30c and the fourth relay device 30d may be determined as overcurrent.

However, in the third relay device 30c, since the phase difference θ3 is located in the first range, the direction (or the third direction) of the third current signal at the third node N3 is forward (the third at the second substation). Direction toward the substation). In addition, the fourth relay device 30d may determine the direction (or the fourth direction) of the fourth current signal at the fourth node N4 in the reverse direction (the direction from the third substation toward the second substation).

At this time, since the third direction and the fourth direction of the third relay device 30c and the fourth relay device 30d are different, it may be determined that the second power line 20b is normal. However, since the third signal is output, the third relay device 30c and the fourth relay device 30d may be determined as an external fault, not an internal fault. Accordingly, the third relay device 30c may output a control signal that maintains the electrical connection of the third breaker 40c. Further, the fourth relay device 30d may output a control signal that maintains the electrical connection of the fourth breaker 40d and transmit it to the fourth relay device 40d. Accordingly, the fourth relay device 40d generates an error in the process of receiving information on the third direction from the third relay device 40c, so that even if it is determined that the third direction and the fourth direction are the same, the fourth breaker ( 40d) electrical connection. Accordingly, even if the relay device makes a wrong determination about the direction of the current, it can be easily corrected.

In this way, the relay device according to the embodiment can prevent the blocking control operation of the circuit breaker from being malfunctioned by a wrong determination in the relay device. Furthermore, separation between systems on a faulty line is performed only in the case of an internal failure, and in the case of an external failure rather than an internal failure, the electrical connection from the circuit breaker can be suppressed to prevent separation between the systems. In this way, it is possible to minimize the power failure zone by accurately separating the system.

The term '~ unit' used in this embodiment refers to hardware components such as software or field-programmable gate array (FPGA) or ASIC, and '~ unit' performs certain roles. However, '~ wealth' is not limited to software or hardware. The '~ unit' may be configured to be in an addressable storage medium or may be configured to reproduce one or more processors. Thus, as an example, '~ unit' refers to components such as software components, object-oriented software components, class components and task components, processes, functions, attributes, and procedures. , Subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, database, data structures, tables, arrays, and variables. The functions provided within components and '~ units' may be combined into a smaller number of components and '~ units', or further separated into additional components and '~ units'. In addition, the components and '~ unit' may be implemented to play one or more CPUs in the device or secure multimedia card.

The embodiments have been mainly described above, but this is merely an example and does not limit the present invention, and those of ordinary skill in the art to which the present invention pertains have not been exemplified above in a range that does not depart from the essential characteristics of the present embodiment. It will be appreciated that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be implemented by modification. And differences related to these modifications and applications should be construed as being included in the scope of the invention defined in the appended claims.

Claims (10)

A first receiver configured to receive a first current signal and a first voltage signal on a first node adjacent to the first substation on a power line disposed between a first substation and a second substation adjacent to the first substation;
An output unit configured to output a first signal when the first current signal is greater than a preset value;
A detector configured to detect a first direction that is a direction of a first current signal at the first node by using a phase difference between the first current signal and the first voltage signal;
A second receiver configured to receive a second direction that is a direction of a second current signal on a second node adjacent to the second substation; And
When the first signal is output and the first direction and the second direction are the same, the power line is determined as a failure, and when the first signal is output and the first direction and the second direction are different, the A relay unit comprising a; determining unit for determining the power line as normal.
According to claim 1,
A relay device including a control unit that outputs a control signal that cuts off the electrical connection of the first circuit breaker connected to the first node when the determination unit determines that it is a failure.
According to claim 2,
The control unit outputs a control signal that maintains the electrical connection of the second circuit breaker connected to the second node when the determination unit determines that it is normal.
According to claim 1,
The relay device in which the first node and the second node are spaced apart.
According to claim 1,
The detecting unit detects the first direction in the forward direction when the phase difference between the first current signal and the first voltage signal is in the first range, and the first direction in the reverse direction in the second range.
The method of claim 5,
The first range is -90 degrees to 90 degrees relay device.
The method of claim 5,
The second range is 90 to -90 degrees relay device.
According to claim 1,
And a transmitting unit transmitting the first direction to the outside.
The method of claim 8,
The transmitting unit relays a control signal that maintains the electrical connection output from the control unit to the outside.
According to claim 1,
The power line is a relay device that is electrically connected to the load.

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