KR20210051787A - System and method for anti-islanding of distributed power generation - Google Patents

Abstract

The present invention relates to a system for anti-islanding of dispersed generation, which comprises: a breakdown determining module for determining whether a breakdown occurs in a distribution system, based on at least one of a current and a voltage in the distribution system linked to the dispersed generation; a backward current sensing module for sensing the occurrence of a backward current caused by islanding of the dispersed generation; a lead-in switch interposed between the dispersed generation and the distribution system to respond to the sensed occurrence of overcurrent greater than the capacity of the dispersed generation and then block the connection between the distribution system and the dispersed generation; and a protecting unit disposed in the distribution system to control connection to the distribution system, based on the occurrence of a breakdown as determined by the breakdown determining module and occurrence of a backward current sensed by the backward current sensing module.

Description

Distributed power alone operation prevention system and method{SYSTEM AND METHOD　FOR ANTI-ISLANDING　OF　DISTRIBUTED POWER GENERATION}

The present invention relates to a system and method for preventing independent operation of a distributed power supply, and a distributed type controlling an inlet switch and a protection device based on whether a reverse current occurs due to the independent operation of a distributed power supply and an overcurrent above the distributed power generation capacity. It relates to a system and method for preventing single power operation.

Research and development on distributed power sources such as solar power generation, wind power reversal, and fuel cell power generation are being actively conducted in order to respond to changes and demands in the electric energy field, such as an increase in power consumption and restructuring of the power industry.

On the other hand, when an accident occurs in the distribution system and the circuit breaker operates or the power supply from the distribution substation is cut off by operating a switch for work, a situation in which some sections separated from the main system are supplied with only the power generation facilities of the distributed power supply. That is, a situation in which the distributed power supply operates alone may occur.

As described above, when the distributed power supply is operated alone, a reverse current may occur in the distribution system. Accordingly, problems such as the risk of an electric shock accident for the operator, the risk of malfunction and failure of the distributed power supply, delay in the restoration of the distribution system, etc. Can occur.

In this regard, conventionally, only the inverter installed by the power generation company has a function to prevent independent operation of the distributed power source, and thus, there is a possibility that the function to prevent the independent operation does not operate when the inverter is defective. In addition, when the independent operation prevention function of the inverter did not work, there was a concern of a safety accident due to the occurrence of reverse pressure in the distribution system.

The background technology of the present invention is disclosed in Korean Patent Publication No. 10-1656313 (2016.09.05.)'a device for preventing independent operation of a distributed power system and a method using the same.'

The present invention was invented to solve the above-described problem, and an object according to an aspect of the present invention is a draw-in switch and an inlet switch on the basis of whether a reverse current occurs due to a single operation of a distributed power source and whether an overcurrent above the distributed power generation capacity occurs. It is to provide a system and method for preventing independent operation of a distributed power supply that controls a protective device.

A system for preventing independent operation of a distributed power supply according to an aspect of the present invention includes a failure determination module for determining the occurrence of a failure of the distribution system based on at least one of current and voltage of a distribution system to which the distributed power supply is connected, and the distributed power supply. A reverse current detection module for detecting the occurrence of a reverse current by a single operation of the power distribution system, provided between the distributed power supply and the distribution system, in response to detecting the occurrence of an overcurrent above the distributed power generation capacity, the distribution system and the An inlet switch that blocks the connection between distributed power sources, and the distribution system, provided on the distribution system, based on whether a failure determined through the failure determination module and whether a reverse current detected through the reverse current detection module has occurred. It characterized in that it comprises a protection device for controlling the connection of.

In the present invention, the inlet switch is characterized in that it includes at least one of an epoxy insulated fault interrupter (EFI) and a cut-out switch.

In the present invention, the pull-in switch is characterized in that it generates an alarm in response to detecting the occurrence of an overcurrent that exceeds the distributed power generation capacity.

In the present invention, the protection device is characterized in that it is a recloser.

In the present invention, the protection device performs line separation or opening in response to determining the occurrence of a failure through the failure determination module, and then reclosing based on the occurrence of reverse current detected through the reverse current detection module. Characterized in determining whether or not.

In the method for preventing independent operation of a distributed power source according to an aspect of the present invention, the failure determination module determines the occurrence of a failure of the distribution system based on at least one of current and voltage of a distribution system to which the distributed power supply is connected. The current detection module, detecting the occurrence of reverse current due to the independent operation of the distributed power supply, and the protection device, whether a failure determined through the failure determination module has occurred, and the reverse current detected through the reverse current detection module It characterized in that it comprises the step of controlling the connection of the distribution system based on whether or not.

In the present invention, the protection device is characterized in that it is a recloser.

In the controlling step in the present invention, the protection device, after performing line separation or opening in response to determining the occurrence of a failure through the failure determination module, determines whether or not the reverse current detected through the reverse current detection module occurs. It is characterized in that it is determined whether or not to perform reclosing on the basis of.

In the present invention, in response to detecting an occurrence of an overcurrent equal to or greater than the distributed power generation capacity, the pull-in switchgear further comprises the step of disconnecting the connection between the distribution system and the distributed power supply.

In the present invention, the inlet switch is characterized in that it includes at least one of an epoxy insulated fault interrupter (EFI) and a cut out switch.

In the blocking step in the present invention, the inlet switch is characterized in that it generates an alarm in response to detecting the occurrence of an overcurrent that exceeds the distributed power generation capacity.

It is possible to prevent accidents due to reverse current caused by the independent operation of the distributed power supply by controlling the incoming switchgear and protection devices based on whether reverse current occurs due to independent operation of the distributed power supply and overcurrent over the generation capacity of the distributed power supply occurs.

1 is an exemplary view illustrating a system for preventing independent operation of a distributed power source according to an embodiment of the present invention.
2 is a flowchart illustrating a method of preventing independent operation of a distributed power supply according to an embodiment of the present invention.

Hereinafter, a system and method for preventing independent operation of a distributed power supply according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is an exemplary view illustrating a system for preventing independent operation of a distributed power supply according to an embodiment of the present invention.

Referring to FIG. 1, the system for preventing independent operation of a distributed power supply according to an embodiment of the present invention includes a distribution system 10 to which a distributed power supply 100 is connected, a failure determination module 200, and a reverse current detection module 300. ), may include a retractable switch 400 and a protection device 500.

The distributed power supply 100 may be connected to the distribution system 10 to supply power to the distribution system 10. For example, the distributed power supply 100 may supply power to the distribution system 10 in connection with the distribution system 10 of a power sales business entity (eg, Korea Electric Power Corporation).

Meanwhile, the distributed power supply 100 may include a renewable energy source such as a solar power generator, a fuel cell generator, a gas engine generator, a wind power generator, or a hydro power generator. However, the present embodiment is not limited thereto, and various forms of the distributed power supply 100 may be employed.

The failure determination module 200 may determine the occurrence of a failure of the distribution system 10 based on at least one of a current and a voltage of the distribution system 10 to which the distributed power supply 100 is connected.

According to an embodiment of the present invention, the failure determination module 200 is provided in a power meter (not shown) installed in the distribution system 10, a protection device 500, or an inlet switch 400, and the distribution system 10 It is possible to measure the current or voltage flowing through and determine the occurrence of a failure of the distribution system 10 based on the measured current or voltage.

For example, the failure determination module 200 may determine that a failure has occurred when an overcurrent or an overvoltage occurs in the distribution system 10.

In addition, the failure determination module 200 may be installed on the distribution system 10 at regular intervals to determine the location of the failure. When it is determined that a failure has occurred in the power distribution system 10, the failure determination module 200 may generate failure information including location information at which the failure has occurred.

The reverse current detection module 300 may detect the occurrence of reverse current due to the independent operation of the distributed power supply 100.

For example, the reverse current detection module 300 may be provided in the protection device 500 to detect a reverse current flowing from the distributed power supply 100 to the protection device 500.

When the reverse current flowing from the distributed power supply 100 to the protection device 500 is detected by the independent operation of the distributed power supply 100, the reverse current detection module 300 detects reverse current including whether or not reverse current detection occurs. Can generate information.

The inlet switch 400 is provided between the distributed power supply 100 and the distribution system 10, in response to detecting the occurrence of an overcurrent over the generation capacity of the distributed power supply 100, the distribution system 10 and the distributed power supply You can block the connection between (100).

For example, the inlet switch 400 may be installed between the branch point of the distribution system 10 and the distributed power supply 100. In addition, the inlet switch 400 measures the current flowing through the distribution system 10 through the failure determination module 200 provided in the inlet switch 400 or a current sensor (not shown) provided in the inlet switch 400, and When the overcurrent of the distributed power supply 100 is measured, the inlet switch 400 may be opened to cut off the connection between the distribution system 10 and the distributed power supply 100.

The inlet switch 400 may separate the distributed power supply 100 from the distribution system 10 when an overcurrent greater than the generation capacity of the distributed power supply 100 is sensed. On the other hand, the inlet switch 400 may maintain the connection between the distributed power supply 100 and the distribution system 10 when an overcurrent greater than the generation capacity of the distributed power supply 100 is not detected.

According to an embodiment of the present invention, the inlet switch 400 may include at least one of an epoxy insulated fault interrupter (EFI) and a cut-out switch.

Epoxy Insulated Fault Interrupters (EFI) can block fault current by extinguishing arcs using epoxy with excellent insulation and arc extinguishing ability as an insulating medium.

The cut-out switch can be used to protect the device from overcurrent due to short-circuit, ground fault, or overload. When a fault current flows to the cutout switch, the fuse link is melted and the arc heat generated on the inner wall of the fuse box The material of is decomposed to generate insulating gas, and accordingly, the arc can be extinguished to block the fault current.

However, the present embodiment is not limited thereto, and various methods capable of blocking the current between the distributed power supply 100 and the distribution system 10 may be employed.

In addition, the inlet switch 400 may generate an alarm in response to detecting the occurrence of an overcurrent equal to or greater than the power generation capacity of the distributed power supply 100.

For example, the inlet switch 400 generates an alarm for controlling the connection between the distributed power supply 100 and the distribution system 10 when the occurrence of overcurrent exceeding the generation capacity of the distributed power supply 100 is detected. : Server) or distributed power supply 100 can be generated by the administrator.

The protection device 500 is provided on the distribution system 10, based on the occurrence of a failure determined through the failure determination module 200 and the occurrence of a reverse current detected through the reverse current detection module 300. You can control the connection.

For example, the protection device 500 may control the connection between the failure point and the substation based on whether a failure occurs and whether a reverse current occurs.

Meanwhile, the protection device 500 may be a recloser.

When a temporary overcurrent occurs in the distribution system 10, the recloser immediately disconnects and re-enters the distribution system 10 to induce normal operation in case of a temporary failure. In case of a permanent failure, it is opened and reopened according to the set number of jumps. It is a circuit breaker that is completely opened (locked-out) by repeating the closing.

For example, if an overcurrent occurs in the distribution system 10 due to a flashover accident due to contact with birds and trees, strong wind or lightning, etc., the recloser classifies the overcurrent occurrence as a temporary failure, and automatically re-inputs after opening. The power distribution system 10 is recovered, but the overcurrent occurrence is classified as a permanent failure if the power distribution system 10 does not recover even after repeating open re-input (e.g., 2 to 3 times) according to the set number of jumps. It can be completely opened (locked out) to make it into a complete power outage state.

At this time, when the protection device 500 is re-input in a situation where a reverse current occurs in the distribution system 10, the reverse current by the independent operation of the distribution system 10 supplied from the substation and the distributed power supply 100 is not synchronized. Although there is a possibility that a spillover failure may occur in the distribution system, the conventional technology has a problem in that the protection device is repeatedly re-inserted 2 to 3 times regardless of the occurrence of reverse current.

According to an embodiment of the present invention, the protection device 500 performs line separation or opening in response to determining the occurrence of a failure through the failure determination module 200, and then detects it through the reverse current detection module 300. It is possible to determine whether to perform reclosing based on whether or not reverse current is generated.

Reclosing is a process of re-inserting the protection device 500 after opening it. In the event of an accident in the distribution system 10, the protection device 500 trips both ends of the distribution system 10, and a certain period of time has elapsed. This means that the protection device 500 is reinserted.

Distributed power supply 100 according to an embodiment of the present invention, when it is determined that a failure has occurred in the distribution system 10 through the failure determination module 200, the distribution system 10 section in which the failure has occurred. After the line separation or opening for separating the line is performed, whether to perform reclosing may be determined based on whether the reverse current detected through the reverse current detection module 300 is generated.

For example, the protection device 500 does not perform reclosing if a reverse current is still detected after the line is separated or opened, and immediately opens the distribution system 10 to completely open the distribution system supplied from the substation ( 10) It is possible to prevent a spillage failure that occurs when the reverse currents caused by the independent operation of the distributed power supply 100 are not synchronized with each other.

On the other hand, the protection device 500 repeats the open input (e.g., 2 to 3 times) according to the set number of jumps if reverse current is not detected after the line is separated or opened. When recovery of the power distribution system 10 is impossible, it is classified as a permanent failure and is completely unlocked (lock-out) to make it into a complete power failure state.

In the method for preventing independent operation of the distributed power supply 100 according to an embodiment of the present invention, when a reverse current occurs due to independent operation by the distributed power supply 100, the distributed power supply 100 is used to block the reverse current. By using the inlet switch 400 to separate it from the distribution system, and using the protection device 500 to block the breakdown section, it is more possible to prevent spreading failure due to overcurrent and reverse current over the generation capacity of the distributed power supply 100. You can definitely block it.

2 is a flowchart illustrating a method of preventing independent operation of the distributed power supply 100 according to an embodiment of the present invention.

Referring to FIG. 2, the method for preventing independent operation of the distributed power supply 100 according to an embodiment of the present invention includes determining the occurrence of a failure (S100), detecting the occurrence of a reverse current (S200), and controlling the connection. It may include step (S300).

In the determining step (S100), the failure determination module 200 determines the occurrence of a failure of the distribution system 10 based on at least one of the current and voltage of the distribution system 10 to which the distributed power supply 100 is connected. I can.

For example, the failure determination module 200 is installed in the distribution system 10 at regular intervals, measures the current or voltage flowing through the distribution system 10, and based on the measured current or voltage, the distribution system 10 It is possible to determine whether or not a failure has occurred.

In the determining step (S100), when it is determined that a failure has occurred in the power distribution system 10, the failure determination module 200 generates failure information including location information of the section in which the failure has occurred, and identifies the section in which the failure has occurred. The fault information can be transmitted to the protection device 500 that can be blocked.

According to another embodiment of the present invention, in the determining step (S100), the failure detection module transmits failure information to a server (not shown) that controls the inlet switch 400 so that the server controls the protection device 500. can do.

In the sensing step (S200), the reverse current detection module 300 may detect generation of a reverse current due to the independent operation of the distributed power supply 100.

When a failure occurs in the distribution system 10 or when the distributed power supply 100 operates alone, a reverse current may occur from the distributed power supply 100 to the protection device 500.

When a reverse current occurs in this way, the reverse current detection module 300 detects the generated reverse current, generates reverse current detection information for controlling the protection device 500, and saves the generated reverse current detection information to the protection device ( 500).

According to another embodiment of the present invention, in the detecting step (S200), the reverse current detection module 300 transmits reverse current detection information to the server controlling the protection device 500 so that the server transmits the protection device 500. Can be controlled.

In the controlling step (S300), the protection device 500 is based on the occurrence of the fault determined through the fault determination module 200 and the occurrence of the reverse current detected through the reverse current detection module 300, the accident occurrence point and the substation. You can control the connection between them.

In the controlling step (S300), the protection device 500 performs line separation or opening in response to determining the occurrence of a failure through the failure determination module 200, and then reversing detected through the reverse current detection module 300. It is possible to decide whether to perform reclosing based on whether or not a current has occurred.

For example, the protection device 500 does not perform re-closing in a situation in which reverse current is still occurring after the line separation or opening is performed, and the distribution system 10 is immediately opened to completely open the distribution system supplied from the substation. It is possible to prevent a spillover failure that occurs when the reverse currents caused by the single operation of the system 10 and the distributed power supply 100 are not synchronized with each other.

On the other hand, after the protection device 500 performs line separation or opening, in a situation where no reverse current occurs, the power distribution system 10 repeats open input (e.g., 2 to 3 times) according to the set number of jumps. When the power distribution system 10 cannot be recovered, it is classified as a permanent failure and is completely unlocked (lock-out) to make it into a complete power failure state.

In the method for preventing independent operation of the distributed power supply 100 according to an exemplary embodiment of the present invention, in response to detecting the occurrence of an overcurrent above the generation capacity of the distributed power supply 100, the inlet switch 400 is connected to the distribution system and the distributed power supply ( It may further include a step (S400) of blocking the connection between 100).

In the blocking step (S400), the inlet switch 400 may cut off the connection between the distribution system 10 and the distributed power supply 100 in response to detecting the occurrence of an overcurrent that is equal to or greater than the generation capacity of the distributed power supply 100. .

When a failure occurs in the distribution system 10, if the distributed power supply 100 operates alone, an overcurrent of more than the generation capacity of the distributed power supply 100 may occur from the distributed power supply 100 to the distribution system 10.

In this way, when the occurrence of overcurrent above the power generation capacity of the distributed power supply 100 is detected in the distribution system 10, the inlet switch 400 prevents overcurrent by disconnecting the power distribution system 10 and the distributed power supply 100. The damage caused by can be prevented.

On the other hand, when the generation of the reverse current is not detected by the reverse current detection module 300, the inlet switch 400 may maintain the connection between the distributed power supply 100 and the distribution system 10.

In the blocking step (S400), the inlet switch 400 may generate an alarm in response to detecting the occurrence of an overcurrent that exceeds the generation capacity of the distributed power supply 100.

For example, the inlet switch 400 generates an alarm for controlling the connection between the distributed power supply 100 and the distribution system 10 when an overcurrent exceeding the generation capacity of the distributed power supply 100 is generated. Server) or distributed power supply 100 may be generated by the administrator.

Meanwhile, the controlling step S300 and the blocking step S400 may be performed simultaneously.

As described above, the system and method for preventing independent operation of the distributed power supply 100 according to an embodiment of the present invention include whether or not reverse current is generated by the independent operation of the distributed power supply 100 and the generation capacity of the distributed power supply 100 By controlling the inlet switch 400 and the protection device 500 based on whether an overcurrent occurs, an accident due to a reverse current caused by a single operation of the distributed power supply 100 can be prevented.

The implementation described herein may be implemented in, for example, a method or process, an apparatus, a software program, a data stream or a signal. Although discussed only in the context of a single form of implementation (eg, only as a method), the implementation of the discussed features may also be implemented in other forms (eg, an apparatus or program). The device may be implemented with appropriate hardware, software and firmware. The method may be implemented in an apparatus such as a processor, which generally refers to a processing device including, for example, a computer, a microprocessor, an integrated circuit or a programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, personal digital assistants (“PDAs”) and other devices that facilitate communication of information between end-users.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those of ordinary skill in the art to which the present technology pertains, various modifications and other equivalent embodiments are possible. I will understand. Therefore, the true technical protection scope of the present invention should be determined by the following claims.

10: distribution system
100: distributed power
200: fault determination module
300: reverse current detection module
400: inlet switch
500: protective device

Claims (11)

A failure determination module for determining occurrence of a failure of the distribution system based on at least one of current and voltage of a distribution system to which a distributed power supply is connected;
A reverse current detection module for detecting the occurrence of a reverse current by the independent operation of the distributed power
A pull-in switch provided between the distributed power supply and the distribution system, in response to detecting an occurrence of an overcurrent of the distributed power generation capacity or higher, to cut off a connection between the distribution system and the distributed power supply; And
And a protection device provided on the distribution system and controlling the connection of the distribution system based on whether a failure determined through the failure determination module and whether a reverse current detected through the reverse current detection module occurs. Distributed power alone operation prevention system characterized by.
The method of claim 1,
The inlet switch is a distributed power alone operation prevention system, characterized in that it comprises at least one of an epoxy insulated fault interrupter (EFI; Epoxy Insulated Fault Interrupter) and a cut-out switch (Cut-Out Switch).
The method of claim 1,
The retractable switchgear generates an alarm in response to detecting an occurrence of an overcurrent equal to or greater than the distributed power generation capacity.
The method of claim 1,
The protection device is a distributed power supply single operation prevention system, characterized in that the recloser (Recloser).
The method of claim 1,
The protection device performs line separation or opening in response to determining the occurrence of a failure through the failure determination module, and then determines whether to perform reclosing based on the occurrence of reverse current detected through the reverse current detection module. Distributed power alone operation prevention system, characterized in that.
Determining, by a failure determination module, occurrence of a failure of the distribution system based on at least one of a current and a voltage of a distribution system to which a distributed power supply is connected;
Detecting, by a reverse current detection module, occurrence of a reverse current due to independent operation of the distributed power supply; And
And controlling, by the protection device, the connection of the distribution system based on whether a failure determined through the failure determination module and whether a reverse current detected through the reverse current detection module occurs. How to prevent single power operation.
The method of claim 6,
The protection device is a method for preventing independent operation of a distributed power supply, characterized in that the recloser.
The method of claim 6, wherein in the controlling step,
The protection device performs line separation or opening in response to determining the occurrence of a failure through the failure determination module, and then determines whether to perform reclosing based on the occurrence of reverse current detected through the reverse current detection module. Distributed power alone operation prevention method, characterized in that.
The method of claim 6,
In response to detecting an occurrence of an overcurrent equal to or greater than the distributed power generation capacity, by a pull-in switch, blocking the connection between the distribution system and the distributed power supply; further comprising: a method for preventing independent operation of a distributed power supply. .
The method of claim 9,
The inlet switch is a method for preventing independent operation of a distributed power source, characterized in that it comprises at least one of an epoxy insulated fault interrupter (EFI) and a cut out switch.
The method of claim 9, wherein in the blocking step,
The inlet switchgear generates an alarm in response to detecting an occurrence of an overcurrent equal to or greater than the distributed power generation capacity.

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