KR101691928B1 - Coordination of protection system and coordination of protection method - Google Patents

Abstract

More particularly, the present invention relates to a protection cooperative system and a protection cooperative method, and more particularly, it relates to a protection cooperative system and a protection cooperative method, in which a current limiter operates by a short- And more particularly, to a protection cooperative system and a protection cooperative method capable of eliminating faults and recovering a power distribution system.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooperative system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a protection cooperative system and a protection cooperative method, and more particularly, to a protection cooperative system and a protection cooperative method in which a current limiter operates as a current for a short time of a short potential difference.

In the underground distribution line, the difference of the maximum fault current according to the fault location is very small. Therefore, it is difficult to apply the selective interruption through the cooperative protection of one time according to the maximum fault current. Underground distribution lines are often installed in urban areas, and line impedance is lower than that of processed lines. Therefore, the fault current is relatively large, and the difference in the fault current due to the high fault is very small, which makes it difficult to cooperate in the protection. Therefore, for the underground line, the fault section is determined and opened through the cooperation of the substation breaker and the switch. According to this method, a blackout occurs in the healthy section due to the opening of the circuit breaker, and the failure time also occurs at a certain portion.

Assuming that a circuit breaker is placed in series with an underground wire, most fail currents will fall into the instantaneous operating range of the potential and posterior relay if a fault occurs. Therefore, it is difficult to select and shut off due to simultaneous tripping. At this time, if the fault current is quickly reduced through the current limiter to the momentary operation region of the electromotive force and the one-time operation region of the posterior relay, the protection cooperation becomes possible. In addition, it is possible to block / isolate the fault section only. In the healthy section, the system is restored without additional power failure, and the reliability of supply is improved.

FIG. 1 is a block diagram showing a concept of protection cooperating with a conventional underground distribution line.

Fig. 2 is a graph 1 showing a concept of protection cooperating with a conventional underground distribution line.

FIG. 3 is a graph 2 showing a concept of protection cooperating with a conventional underground distribution line.

In the protection cooperation of the conventional underground distribution line as shown in FIG. 1, when a failure occurs in the branch line, it is impossible to cooperate in the instantaneous protection area in both the field electric potential and the rear relay, as shown in the T-C curve of FIG. The fault current is placed in the shaded region of FIG. 3 by disposing the fault current limiter 300 to reduce the fault current by operating the fault current limiter 300 when a fault occurs. In this case, it is possible to cooperate with protection because the electromotive force is in the instantaneous operation area and the posterior relay is in the temporary operation area.

If it is not a protected period of the electrometer or if the electrometer circuit breaker 100 malfunctions, the posterior relay operates. In this case, the delay is delayed by one hour delay time until the failure of the rear circuit breaker 200 is removed. The current limiting impedance of the short-circuited fan (300) must be supplied with the fault current by the duration of this fault current, and the current and time history must be secured. In the case of the resistor type, since the heat generated by the fault current also becomes considerably large, there is a problem that the size of the resistance of the current resistance must be increased. Also, if the temperature rises too much, it can be put back into the system after cooling. The same goes for the Hallyu reactor. In order to minimize the temperature rise, the size of the current-flow impedance device must be increased, which means that the size of the short-circuited fan 300 is increased.

Therefore, in order to solve the limitations of the related art, the present specification discloses that the short-range current flows by the short-circuiting time of the potential difference, minimizes the thermal tolerance of the current impedance, And to provide a protection cooperation system and a protection cooperation method that can recover the system more quickly.

A current limiting device installed between the first protection device installed at the first point of the distribution system and the second protection device installed at the second point of the distribution system disclosed in this specification for solving the above problems is characterized in that a fault current And a switching unit for switching the converter of the fault current to the current impedance unit, wherein the switching unit is switched such that the fault current is limited by a blocking time that is a blocking operation condition of the second protective device .

In one embodiment, the first point may be the trunk of the distribution system, and the second point may be a branch line that branches off from the trunk.

In one embodiment, the first protective device and the second protective device can operate in response to the respective fault currents of different sizes.

In one embodiment, the fault current may be limited in the magnitude of the current depending on the impedance magnitude of the current-flow impedance section.

Further, in order to solve the above-mentioned problems, the protection cooperation system disclosed in this specification is characterized in that a first protection device installed at a first point of a distribution system, a second protection device installed at a second point of the distribution system, And a current limiter provided between the second protective device and limiting the fault current of the power distribution system, the current limiter limits the fault current by a cutoff time which is a cutoff operation condition of the second protective device.

In one embodiment, the first point may be the trunk of the distribution system, and the second point may be a branch line separate from the trunk.

In one embodiment, the first protective device and the second protective device can operate in response to the respective fault currents of different sizes.

In one embodiment, the fault current may be limited in magnitude of the current depending on the magnitude of the impedance of the current limiter.

In one embodiment, the current limiter can be restored after limiting the fault current by the cut-off time of the second protective device when the fault current occurs at either the first point or the second point have.

Further, in order to solve the above-mentioned problems, the protection cooperative method disclosed in the present specification is characterized in that the first protection device installed at the first point, the second protection device installed at the second point of the distribution system, A fault current detected in the power distribution system in a power distribution system including a current limiter installed between protective devices; limiting the fault current by a cut-off time which is a cutoff operation condition of the second protective device; Determining whether the second protection device operates according to a limited size of the fault current, determining whether the first protection device operates according to the size of the fault current, .

In one embodiment, the step of determining whether to operate the second protective device may include determining if the magnitude of the fault current limited by the current limiter is greater than the cut-off size of the second protective device, The operation of the second protective device can be determined.

In one embodiment, the step of determining whether or not the first protective device is operated may include the steps of: when the magnitude of the fault current recovered after being limited by the current limiter is greater than the blocking magnitude of the first protective device, It is determined that the fault current has occurred, and the operation of the first protective device can be determined.

The protection cooperative system and the protection cooperative method disclosed in this specification are effective in minimizing the thermal tolerance of the current impedance due to the operation of the current limiter by the breaking time of the short potential difference.

The protection cooperative system and the protection cooperative method disclosed in this specification can minimize the thermal tolerance of the current impedance, thereby making it easier to design a fault current limiter and a protection cooperative system including the same.

The protection cooperative system and the protection cooperation method disclosed in this specification have the effect that the breaker operation of the rear circuit breaker becomes faster due to the operation of the short circuit current by the breaking time of the potential difference short circuit and the recovery of the fault circuit and the power distribution system becomes faster have.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a concept of protection cooperating with a conventional underground distribution line. FIG.
2 is a graph showing a concept of protection cooperating with a conventional underground distribution line.
FIG. 3 is a graph illustrating a concept of protection cooperating with a conventional underground distribution line.
4 is a block diagram showing the configuration of a fault current limiter of the protection cooperative system disclosed in this specification;
5 is a circuit diagram showing a configuration of the protection cooperation system disclosed in this specification;
Figure 6 is a flow chart illustrating the sequence of the protection cooperative method disclosed herein.

The invention disclosed herein can be applied to a protection cooperation system and a protection cooperation method. However, the technology disclosed in this specification is not limited to this, and all protection devices, such as a short-circuit current limiter, a relay, a relay, a surge absorber, an electromagnetic contactor, and a breaker, which limit the breakdown current of an existing line to which the technical idea of the present invention can be applied, It can also be applied to the current limiter circuit included in the device. In particular, it can be effectively applied to surveillance devices and protection devices that protect lines that require cooperation with the system and peripheral protection devices.

It is noted that the technical terms used herein are used only to describe specific embodiments and are not intended to limit the scope of the technology disclosed herein. Also, the technical terms used herein should be interpreted as being generally understood by those skilled in the art to which the presently disclosed subject matter belongs, unless the context clearly dictates otherwise in this specification, Should not be construed in a broader sense, or interpreted in an oversimplified sense. In addition, when a technical term used in this specification is an erroneous technical term that does not accurately express the concept of the technology disclosed in this specification, it should be understood that technical terms which can be understood by a person skilled in the art are replaced. Also, the general terms used in the present specification should be interpreted in accordance with the predefined or prior context, and should not be construed as being excessively reduced in meaning.

Also, the singular forms "as used herein include plural referents unless the context clearly dictates otherwise. In this specification, the terms "comprising ", or" comprising ", etc. should not be construed as necessarily including the various elements or steps described in the specification, Or may be further comprised of additional components or steps.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals denote like or similar elements, and redundant description thereof will be omitted.

Further, in the description of the technology disclosed in this specification, a detailed description of related arts will be omitted if it is determined that the gist of the technology disclosed in this specification may be obscured. It is to be noted that the attached drawings are only for the purpose of easily understanding the concept of the technology disclosed in the present specification, and should not be construed as limiting the spirit of the technology by the attached drawings.

Hereinafter, the protection cooperation system and the protection cooperation method disclosed in this specification will be described with reference to Figs.

Fig. 4 is a block diagram showing the configuration of a current limiter of the protection cooperation system disclosed in this specification.

5 is a circuit diagram showing the configuration of the protection cooperation system disclosed in this specification.

6 is a flowchart showing the sequence of the protection cooperation method disclosed in this specification.

First, referring to Fig. 4, the rectifier disclosed in this specification will be described.

The current limiter disclosed herein can be a current limiter included in the protection coordination system disclosed herein.

The fault current limiter disclosed herein may be a current limiter applied to the protection cooperative method disclosed herein.

The current limiter 300 is installed at a first protection device installed at a first point of the distribution system and at a second point of the distribution system.

4, the current limiter 300 includes a current-limiting impedance unit 10 for limiting a fault current flowing in the power distribution system, and a switch for switching the converter of the fault current to the current-impedance unit 10, (20), wherein the switching unit (20) is switched so that the fault current is limited by a blocking time that is a blocking operation condition of the second protective device.

The current limiter 300 means a protective device that limits a fault current due to an abnormal condition such as an accident occurring in a system and a line.

The current limiter 300 may be a protector that performs a function of limiting the magnitude and duration of the fault current.

The current limiter 300 can protect the line from the fault current by cooperating with other protection devices such as circuit breakers, switches, relays, and the like that cut off the line.

The fault current may be a current generated by an abnormal condition such as an accident occurring in the system and the line, and having a magnitude greater than a current flowing in a normal period.

That is, since the fault current has a magnitude equal to or higher than the rated current, the fault current may cause a fault in equipment, loads connected to the system and the line.

The fault current may be any one of ground fault, short circuit and overload current generated in the system and the line.

The current-limiting impedance unit 10 and the switching unit 20 included in the current limiter 300 may be connected in a parallel connection manner.

One end of the current-limiting impedance unit 10 and one end of the switching unit 20 are connected to each other. The other end of the current-limiting impedance unit 10 and the other end of the switching unit 20 are connected to the power distribution system Can be installed.

That is, the current flowing in the power distribution system may be energized through at least one of the current-limiting impedance unit 10 and the switching unit 20 when the current-limiting unit is energized.

The current-limiting impedance unit 10 may include at least one impedance element for limiting the fault current.

The impedance element may be at least one of a resistance element and a reactance element.

When the fault current flows to the current impedance section 10, the magnitude of the fault current may be limited by the impedance element.

The impedance element included in the current-limiting impedance unit 10 may be a variable impedance element whose impedance value changes according to the fault current.

The switching unit 20 may include a switch element for switching the conduction of the fault current.

The switching unit 20 can be closed at normal times and opened when the fault current is generated so that the fault current can be switched so that the fault current flows to the current impedance unit 10. [

That is, the current of the power distribution system is normally supplied through the switching unit 20, and when the fault current is generated, the fault current is supplied through the current-frequency impedance unit 10, ). ≪ / RTI >

The switching unit 20 switches the converter of the fault current so that when the fault current occurs in the power distribution system, the fault current is limited by the cutoff time of the second protective device, (10).

That is, the current limiter 300 may limit the fault current by the cut-off time of the second protective device, and restore the limitation of the fault current after the cutoff time.

Hereinafter, the protection cooperation system disclosed in this specification will be described with reference to FIG.

The protection cooperation system disclosed in this specification can include the above-mentioned reflux to provide protection cooperation.

The protection coordination system 500 comprises a first protection device 100 installed at a first point of the distribution system 500 as shown in FIG. 5, a second protection device 100 installed at a second point of the distribution system, 2 protection device 200 and a current limiter 300 installed between the first protection device 100 and the second protection device 200 for limiting the fault current of the power distribution system, (300) limits the fault current by a cut-off time that is a cutoff operation condition of the second protective device (200).

That is, the system 500 may be a system in which the first protection device 100, the second protection device 200, and the current limiter 300 cooperate with each other.

The always-on system 500 may include at least one protective device such as a relay for detecting current, a circuit breaker for blocking the line, and an open / close circuit for opening and closing the line.

In the system 500, the first point may be the trunk of the distribution system.

That is, the first point may be a point near the power supply end to which power is supplied from the power distribution system.

The first point may comprise at least one branch line.

In the system 500, the second point may be a branching line that branches off from the trunk.

That is, the second point may be a point near the lower end of the power distribution system.

That is, the magnitude of the current flowing at the first point may be greater than the magnitude of the current flowing at the second point.

The first point may be protected through the first protective device 100 and the second point may be protected through the second protective device 200. [

The first protective device 100 and the second protective device 200 may be circuit breakers that protect the power distribution system from a fault current.

The first protective device 100 and the second protective device 200 may block the line to protect the power distribution system from the fault current when the fault current is detected through the relay or the like.

The first protective device 100 may be installed at the first point and the second protective device 200 may be installed at the second point to block the line at the point where the first protective device 100 is installed.

That is, the first protective device 100 can protect the trunk line of the power distribution system, and the second protective device 200 can protect the branch line of the power distribution system.

The first protective device 100 and the second protective device 200 can operate in response to the fault currents of different sizes.

That is, since the first protective device 100 protects the trunk with a large current and the second protective device 200 protects the branch line having a small current, the first protective device 100 and the second protective device 200 The magnitude of the blocking current may be different.

The current limiter 300 is provided between the first protective device 100 and the second protective device 200 to limit the fault current and to prevent the fault current from being generated by the second protective device 200 Can be limited.

The fault current limiter 300 limits the fault current by the cut-off time of the second protective device 200 when the fault current occurs at any one of the first point and the second point, .

That is, the fault current is limited by the cutoff time of the second protective device 200 by the current limiter 300, and after the cutoff time, the limit of the current limiter 300 can be restored .

The fault current may be limited in the magnitude of the current according to the magnitude of the impedance of the current limiter 300.

That is, if the impedance of the current limiter 300 is large, the current magnitude of the fault current is greatly limited. If the impedance magnitude is small, the current magnitude of the fault current may be limited to a small value.

With continued reference to Figure 5, a specific embodiment of the system 500 will now be described.

The system 500 having the above-described configuration can protect the distribution system from the fault current generated in the distribution system.

The first protective device may protect the first point from the fault current when the fault current occurs at the first point.

The second protective device may protect the second point from the fault current when the fault current occurs at the second point.

The fault current limiter 300 may limit the fault current when the fault current is generated in the power distribution system, but may be limited by the cutoff time of the second protective device 200.

If the fault current occurs at the second point F2 as shown in FIG. 5, the current limiter 300 may limit the fault current by the cut-off time of the second protective device 200 have.

The operation of the first protective device 200 is delayed due to the limitation of the fault current below the cutoff current of the first protective device 100 and the second protective device 200 is operated at the second point F2, The shutdown operation can be performed by the fault current generated in the power supply.

If the current limiter 300 limits the fault current by the cut-off time of the second protective device 200 and the shutoff operation of the second protective device 200 is performed, the limitation of the fault current is restored , The first point (F1) is maintained intact and the second point (F2) is interrupted by the second protective device (200) so that from the fault current generated at the second point (F2) The system can be protected.

If the fault current occurs at the first point F1 as shown in FIG. 5, the current limiter 300 may limit the fault current by the blocking time of the second protective device 200 have.

The operation of the first protective device 200 is delayed because the failure current is limited to be less than the cutoff current of the first protective device 100 and the second protective device 200 is operated at the first point F1, The fault current generated in the inverter 300 is limited by the inverter 300.

If the cut-off operation of the second protective device 200 is not performed while the current limiter 300 limits the fault current by the cut-off time of the second protective device 200, restricting the fault current The fault current having a magnitude before being limited by the current limiter 300 flows at the first point F1 so that the first protective device 100 can be disconnected.

The first point (F1) is blocked by the first protective device (100) so that the distribution system can be protected from the fault current generated at the first point (F2).

That is, when the fault current is generated at the first point (F1) by limiting the fault current by the cutoff time of the second protective device (200), the current limiter (300) The first protection device 100 is protected by the first protection device 100 and the second protection device 200 is protected when the failure current is generated at the second point F2, So that the power distribution system can be protected by the second protective device (200).

Hereinafter, the protection cooperation method disclosed in this specification will be described with reference to FIG.

The protection cooperation method disclosed in this specification can be a method for protecting cooperation of the power distribution system.

The protection cooperation method disclosed in this specification can be applied to a protection cooperation system.

The protection cooperation method includes a first protection device installed at a first point of the distribution system, a second protection device installed at a second point of the distribution system, and a short-circuited device installed between the first protection device and the second protection device 6 is a flowchart illustrating a method of protecting and cooperating with a power distribution system according to an exemplary embodiment of the present invention. Referring to FIG. 6, the method includes detecting a fault current generated in the power distribution system, (S30) of determining whether the second protective device is in operation in accordance with the limited size of the fault current (S40), restoring the fault current to the normal state (S40), and restoring the fault current And determining whether the first protective device is operated according to the size of the first protective device (S50).

The step (S10) of detecting a fault current generated in the power distribution system may be performed to detect the fault current through a detector or a relay included in the power distribution system.

The step (S10) of detecting a fault current generated in the power distribution system may detect the fault current generated at the first point or the second point.

The step of limiting the fault current (S20) may limit the fault current generated at the first point or the second point.

The step of limiting the fault current (S20) may allow the fault current limiter to limit the fault current by the cut-off time of the second protective device so that the operation of the second protective device can be determined.

The step S30 of determining whether the second protective device is operated may include determining whether the fault current is generated at the second point when the magnitude of the fault current limited by the current limiter is larger than the breaking size of the second protective device And the operation of the second protective device can be determined.

When the operation of the second protective device is determined, the second protective device may block the second point to protect the power distribution system from the fault current.

In the step S40, the current limiter limits the fault current by the cut-off time of the second protective device so that the operation of the current limiter is restored So that the limitation of the fault current can be restored.

Wherein the step of determining whether the first protective device is operated (S50) comprises the steps of: if the magnitude of the fault current recovered after being limited by the current limiter is larger than the cut-off size of the first protective device, The operation of the first protective device can be determined.

When the operation of the first protective device is determined, the first protective device may block the first point to protect the power distribution system from the fault current.

That is, when the fault current occurs at the first point, the first point is blocked by the first protective device so that the first point and the second point are separated from each other Wherein when the fault current occurs at the second point, the second point is blocked by the second protective device so that the first point and the second point are separated, whereby the first protective device and the second The power distribution system can be protected from the fault current by each protective device.

Embodiments of the protection cooperation system and the protection cooperation method disclosed in this specification can be applied to the protection cooperation system and the protection cooperation method with the underground distribution line.

Embodiments of the protection cooperative system and the protection cooperative method disclosed in this specification can be applied to all kinds of circuits such as a short circuit breaker, a switch, a relay, a surge absorber, an electromagnetic contactor, and a circuit breaker that limit the breakdown current of an existing line to which the technical idea of the present invention can be applied Protection devices, and current limiters included in protective devices.

Embodiments of the protection cooperation system and the protection cooperation method disclosed in this specification can be particularly applied to a monitoring apparatus and a protection apparatus that protect a line requiring protection cooperation with a system and a peripheral protection apparatus.

The protection cooperative system and the protection cooperative method disclosed in this specification are effective in minimizing the thermal tolerance of the current impedance due to the operation of the current limiter by the breaking time of the short potential difference.

The protection cooperation system and the protection cooperation method disclosed in this specification can minimize the thermal tolerance of the wave current impedance, thereby facilitating the design of the fault current limiter and the protection coordination system including the same.

The protection cooperative system and the protection cooperation method disclosed in this specification have the effect that the breaker operation of the rear circuit breaker becomes faster due to the operation of the short circuit current by the breaking time of the potential difference short circuit and the recovery of the fault circuit and the power distribution system becomes faster have.

It will be apparent to those skilled in the art that various modifications and changes can be made in the present invention without departing from the spirit or scope of the present invention as defined by the appended claims. And such modifications and the like should be considered to fall within the scope of the following claims.

10: Current-flow impedance unit 20:
100: first protection device 200: second protection device
300: Korean Wave 500: Protection Cooperation System

Claims (9)

A first protective device installed at a first point of the distribution system;
A second protective device installed at a second point of the distribution system; And
And a current limiter provided between the first protective device and the second protective device for limiting a fault current of the power distribution system,
The current-
The fault current is limited by a cut-off time which is a cut-off operation condition of the second protective device,
When the fault current occurs at any one of the first point and the second point,
Restricting the fault current by the cut-off time of the second protective device,
When the fault current occurs at the first point, only the first protective device is operated,
And when the fault current occurs at the second point, only the second protective device is operated. The method according to claim 1,
Wherein the first point
The main line of the power distribution system,
The second point,
And a branch line branching from said trunk line. The method according to claim 1,
Wherein the first protective device and the second protective device comprise:
Wherein the protection cooperating system operates in response to the fault currents of different sizes. The method according to claim 1,
The current-
A current-limiting impedance unit for limiting a fault current flowing in the power distribution system; And
And a switching unit for converting the inverter of the fault current into the current-wave impedance unit. delete The method according to claim 1,
The fault current
Wherein the current magnitude is limited according to the magnitude of the impedance of the current limiter. A first protective device installed at a first point of the distribution system;
A second protective device installed at a second point of the distribution system; And
And a current limiter installed between the first protective device and the second protective device, the method comprising the steps of:
Detecting a fault current occurring in the power distribution system;
Limiting the fault current by the cut-off time which is the shutdown operating condition of the second protective device;
Determining whether the second protective device is in operation according to a limited size of the fault current;
A step of recovering the current limiter normally;
And determining whether the first protective device is operated according to the magnitude of the recovered fault current,
The current-
The fault current is limited by a cut-off time which is a cut-off operation condition of the second protective device,
When the fault current occurs at any one of the first point and the second point,
Restricting the fault current by the cut-off time of the second protective device,
When the fault current occurs at the first point, only the first protective device is operated,
And when the fault current occurs at the second point, only the second protective device is operated. 8. The method of claim 7,
Wherein the step of determining whether to operate the second protective device comprises:
And the operation of the second protective device is determined when it is determined that the fault current is generated at the second point when the magnitude of the fault current limited by the current limiter is larger than the blocking size of the second protective device To cooperate. 8. The method of claim 7,
Wherein the step of determining whether the first protective device is operated comprises:
When the magnitude of the fault current restored after being limited by the current limiter is larger than the cut-off size of the first protective device, it is determined that the fault current has occurred at the first point, and the operation of the first protective device is determined Wherein the protection cooperation method comprises the steps of:

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