KR101069637B1 - Apparatus and method for protecting overcurrent - Google Patents

Abstract

The device that protects the overcurrent generated from the distribution system connected to the distributed power supply includes a measuring unit that measures voltage and current for each phase, a fault detection unit that detects a fault based on the comparison result, and compares the current with a set current. Judging, using the reverse phase direction discrimination element and the normal direction direction discrimination element for each type of failure, the direction discrimination unit for determining whether the failure direction is forward or reverse direction, and in case the failure direction is the forward direction Contains wealth.

Description

Apparatus and method for protecting overcurrent

The present invention relates to an overcurrent protection method and apparatus thereof. More specifically, the present invention relates to a method and apparatus for protecting overcurrent generated in a distribution system to which distributed power supplies are linked.

In the event of a failure in the distribution system, the power supply for the fault current was only the power supply on the substation side, and the fault current was supplied in one direction from the substation to the fault point. Therefore, the protection of the distribution system has basically adopted an overcurrent relay method which does not consider directionality.

However, in the distribution system in which the distributed power supply is connected, the fault current supply source includes a distributed power supply in addition to the substation, and the distribution of the fault current is also distributed in both directions, which causes problems in the existing overcurrent protection system. The most frequent accidents in distribution systems with distributed power sources are malfunctions of protective equipment in the power line with distributed power sources in addition to the accident line.

The transformer for the connection of distributed power supplies uses the Grounded Y-Delta wiring method corresponding to the effective grounding standard specified in KEPCO's distributed power system linkage standards. Therefore, if the linkage transformer is connected to the system regardless of power generation in case of ground fault, the primary ground of the transformer provides the passage of ground fault current.

Since malfunctions of protection equipment in the power line connected with distributed power supply due to other line accidents supplied by substation transformers of the substations of the line with distributed power supply cannot be solved by correcting only the coordination of protection, it is necessary to provide direction discrimination function to the protection equipment for power distribution. It needs to be granted. Here, the direction determination method determines the direction on the basis of two components consisting of a reference amount and an operating amount and the angle between these two components.

The directional determination method does not reflect the failure characteristics of the distributed power supply, and when applied to the distribution system to which the distributed power supply is linked, accurate direction determination may fail according to a failure condition.

The present invention has been proposed to solve the above problems, to provide a method and apparatus for protecting overcurrent generated in a distribution system in which distributed power supplies are linked.

According to an embodiment of the present invention for solving the above problems, the apparatus for protecting the overcurrent generated in the distribution system is connected to the distributed power supply is

A measuring unit measuring voltage and current for each phase; A failure detector for detecting a failure based on a comparison result by comparing the current with a set current; A direction determination unit for determining a type of failure and determining whether the failure direction is in the forward direction or the reverse direction by using the reverse phase direction determination element and the normal direction direction determination element for each of the determined failure types; And a breaker that protects the overcurrent by operating the breaker when the failure direction is the forward direction.

According to another embodiment of the present invention for solving the above problems, a method for protecting overcurrent generated in the distribution system is connected to the distributed power supply is

Measuring voltage and current for each phase in the distribution system by an overcurrent protection device; Comparing the current with a set current to detect a failure based on a comparison result; Determining a failure type and determining a failure direction by using a reverse phase direction determination element and a normal direction direction determination element for each of the determined failure types; And protecting the overcurrent by operating the circuit breaker when the failure direction is the forward direction.

According to an embodiment of the present invention, the overcurrent protection device and its method are added to the operation method of the conventional protection equipment and automatic switchgear, and by applying the direction determination method reflecting the failure characteristics of the distributed power supply, Even if distributed power is additionally connected to the system, the malfunction of the protective device can be prevented.

In addition, the overcurrent protection device and the method are applied to an automatic switchgear, and further provides the operator with fault indicator (FI) information and fault direction information, so that the operator can determine the exact fault location.

FIG. 1 is a circuit diagram illustrating a distribution of fault currents in a distribution system in which distributed power supplies are linked when an accident occurs on another line.
2 is a block diagram showing an overcurrent protection device according to an embodiment of the present invention.
3 is a block diagram showing a direction determining unit according to an embodiment of the present invention.
4 is a vector diagram for determining a reverse phase direction according to an exemplary embodiment of the present invention.
5 is a vector diagram for determining a normal division direction according to an exemplary embodiment of the present invention.
6 is a flowchart illustrating an overcurrent protection method according to an embodiment of the present invention.
7 is a flowchart illustrating a method of determining a failure direction according to an exemplary embodiment of the present invention.
8 is a view showing the configuration and operation of the overcurrent protection method according to an embodiment of the present invention and the protection device to which the device is applied.
FIG. 9 is a circuit diagram illustrating a distribution of fault currents when a distribution automation automation switch is operated in a distribution system in which distributed power supplies are linked.
10 is a flowchart illustrating a method of generating a failure indicator to which a method of determining a failure direction is added according to an exemplary embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Here, the repeated description, well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention, and detailed description of the configuration will be omitted. Embodiments of the present invention are provided to more completely describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity.

Hereinafter, an overcurrent protection method and an apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram illustrating a distribution of fault currents in a distribution system in which distributed power supplies are linked when an accident occurs on another line.

Referring to FIG. 1, when a ground fault occurs at the fault point F1, an image circuit is formed in a first distribution line to which distributed power is connected, and a reverse fault current through which distributed power is supplied is reclosed RC1 ( 10) is detected. At this time, when the magnitude of the fault current is equal to or greater than the corrected value (minimum operating current) of the recloser, the recloser RC1 10 trips due to the protection coordination time difference.

As a result, the recloser (RC1) 10 operates unnecessarily in the first distribution line without a failure, and a power failure occurs in the section below the recloser (RC1) 10 of the first distribution line. At the same time, the recloser (RC1) 10 trips so that the system below the recloser (RC1) 10 experiences single operation and the distributed power supply is also dropped out of the system.

If the second breaker (CB2) 20 corresponding to the protective device of the accident line removes the failure before the recloser RC1 10, the recloser RC1 10 may be removed from the first distribution line. Unnecessary power failure can be prevented.

However, the recloser, which can be called a potential protection device for protection coordination in a distribution system, is generally set faster than a substation breaker, which is a post-protection device. Therefore, the malfunction of the protection equipment in the power line connected with the distributed power supply due to other line accidents supplied by the substation transformer of the substation of the line to which the distributed power is connected cannot be solved only by correction of protection coordination. You need to give it a function.

Next, an overcurrent protection device for selectively applying the direction discrimination method according to the type of failure in the distribution system to which the distributed power supply is connected will be described in detail with reference to FIG. 2.

2 is a block diagram showing an overcurrent protection device according to an embodiment of the present invention.

Referring to FIG. 2, the overcurrent protection device includes a measurement unit 100, a failure detection unit 200, a direction determination unit 300, and a blocking unit 400.

The measuring unit 100 measures the phase voltage and current.

The failure detection unit 200 detects a failure based on a comparison result by comparing the measured current with a previously set current (hereinafter, referred to as "set current"). Here, the set current corresponds to the minimum operating current of the protection device, but is not limited thereto. In addition, the failure detection unit 200 detects a failure when the measured current is greater than or equal to the set current.

The direction determining unit 300 determines the type of failure by using the reverse phase current, and determines whether the failure direction is in the forward direction or the reverse direction by using a specific determination element for each type of the determined failure. Here, the failure type includes an unbalance failure such as ground fault and an equilibrium failure such as a three-phase short circuit failure, and the specific discrimination factor includes an inverse phase direction discrimination element corresponding to an unbalanced failure and a normal direction determination element corresponding to an equilibrium failure. Include.

When the failure direction is in the forward direction, the breaker 400 sends a trip signal to the breaker and operates the breaker. In the reverse direction, the breaker 400 controls the measurement unit 100 to measure voltage and current again without operating the protection device. In addition, the blocker 400 forcibly trips the circuit breaker when the number of times determined by the direction determiner 300 as the reverse failure continuously occurs for a specific number of times or more.

That is, the overcurrent protection device according to the embodiment of the present invention can be implemented in the control device of the protection device, that is, the terminal to prevent unnecessary malfunction of the protection device due to the reverse fault current contributed by the distributed power supply. In addition, the overcurrent protection device can ensure safety even in a state where the reliability of operation of the protection device is not secured, such as when the protection device to be operated is not operated.

Next, the direction determining unit 300 according to an embodiment of the present invention will be described in detail with reference to FIG. 3.

3 is a block diagram showing a direction determining unit according to an embodiment of the present invention.

Referring to FIG. 3, the direction determiner 300 includes a fundamental wave calculator 310, a calculator 320, a failure type determiner 330, and a direction determiner 340.

The fundamental wave calculator 310 extracts the fundamental wave voltage and the fundamental wave current by removing harmonics of the measured voltage and current.

The calculation unit 320 calculates the normal voltage (3V ₁ ), the normal voltage (3I ₁ ), the reverse phase voltage (3V ₂ ), and the reverse phase current (3I ₂ ) using the extracted fundamental wave voltage and the fundamental wave current. do. At this time, the normal voltage 3V1, the normal current 3I ₁ , the reverse phase voltage 3V ₂ , and the reverse phase current 3I ₂ are represented by Equation 1 below.

The failure type determination unit 330 determines whether the failure type is an unbalanced or an equilibrium failure by using the reverse phase current 3I ₂ . In detail, the failure type determination unit 330 determines that an unbalance failure occurs when the reverse phase current 3I ₂ is greater than or equal to a set value, and determines that the balance type failure is less than the set value. Here, the set value is a value corresponding to the reverse phase current when the unbalanced current occurs before failure in the distribution system, but is not limited thereto.

The direction determining unit 340 determines whether the failure direction is the forward direction or the reverse direction by using the reverse phase direction determining element when the type of the failure is determined to be an unbalanced failure and the normal direction direction determining element when the balance type is determined to be the balanced failure. Here, the reverse phase direction discrimination element includes a reverse phase voltage (3V ₂ ), reverse phase current (3I ₂ ), and a maximum sensitivity phase angle (MTA2), and the normal phase direction discrimination element includes a normal phase voltage (3V ₁ ) and a normal phase. Minute current 3I ₁ and maximum sensitivity phase angle MTA ₁ .

In the case of an unbalance failure, the direction determining unit 340 determines the direction as shown in FIG. 4 by using the reverse phase direction determining element. Specifically, the direction determination unit 340 determines that the direction discrimination reference angle T ₂ generated by using the reverse phase direction determination element is in the forward direction when the direction angle reference angle T ₂ is within a setting angle (eg, ± 90 °), and the setting angle range. If it is outside, it is determined in the reverse direction. In this case, the direction discrimination reference angle T ₂ is obtained by using the inverse phase direction determination element as in Equation 2.

In the case of an equilibrium failure, the direction determining unit 340 determines the direction as shown in FIG. 5 by using the normal part direction determining element. In detail, the direction determining unit 340 determines that the direction discrimination reference angle T ₁ generated by using the normal part direction determining element is in the positive direction when it is within a setting angle (for example, ± 90 °), and sets the range of the setting angle. If it is outside, it is determined in the reverse direction. At this time, the direction determination reference angle (T ₁ ) is obtained as shown in Equation 3 by using the phase direction discrimination element.

According to an embodiment of the present invention, the failure type determination unit 330 may determine whether the failure type is an unbalanced fault or an equilibrium failure by using the image split current 3I ₀ other than the reverse phase current 3I2. At this time, the image split current 3I ₀ is expressed as in Equation 4.

However, since the image split current 3I ₀ is not used in the direction determining unit 340, it is more efficient to calculate the type of fault by calculating the reverse phase current used as the reverse phase direction determining element.

Next, an overcurrent protection method according to an embodiment of the present invention will be described in detail with reference to FIG. 6.

6 is a flowchart illustrating an overcurrent protection method according to an embodiment of the present invention. 7 is a flowchart illustrating a method of determining a failure direction according to an exemplary embodiment of the present invention.

Referring to FIG. 6, the overcurrent protection device measures voltage and current for each phase (S100). Next, the overcurrent protection device compares the measured current and the set current corresponding to the minimum operating current of the protection device (S200). At this time, the overcurrent protection device detects a failure when the measured current is more than the set current.

If a failure is detected, the overcurrent protection device determines the failure type by using the reverse phase current, and determines whether the failure direction is the forward direction or the reverse direction by using a specific determination element corresponding to the determined failure type (S300). Here, the failure type includes an unbalance failure and an equilibrium failure, and the specific determination element includes an inverse normal direction determination element corresponding to an unbalance failure and a normal direction direction determination element corresponding to an equilibrium failure.

Next, a method of determining a failure direction according to an embodiment of the present invention will be described in detail with reference to FIG. 7.

Referring to FIG. 7, the overcurrent protection device extracts the fundamental wave voltage and the fundamental wave current by removing harmonics of the measured voltage and current (S301).

The overcurrent protection device calculates the normal voltage (3V1), the normal voltage (3I ₁ ), the reverse phase voltage (3V ₂ ), and the reverse phase current (3I ₂ ) using the extracted fundamental wave voltage and the fundamental wave current (S302). ).

The overcurrent protection device determines whether the reverse phase current 3I ₂ is greater than or equal to the set value (S303). In this case, the overcurrent protection device determines that an unbalance failure occurs when the reverse phase current 3I ₂ is greater than or equal to a set value, and determines that an equilibrium failure is less than the set value.

When the reverse phase current 3I ₂ is greater than or equal to the set value, the overcurrent protection device generates the direction discrimination reference angle T ₂ using the reverse phase direction discrimination element corresponding to the unbalance failure (S304). The overcurrent protection device determines whether the generated direction determination reference angle T ₂ is located within a set angle (eg, ± 90 °) (S305). Next, the overcurrent protection device determines that the direction discrimination reference angle T ₂ is within the set angle (for example, ± 90 °) in the forward direction (S306), and in the reverse direction if it is outside the set angle range (S307).

When the reverse phase current 3I ₂ is smaller than the set value, the overcurrent protection device generates the direction determination reference angle T ₁ using the normal direction direction determining element corresponding to the balanced fault failure (S308). The overcurrent protection device determines whether the generated direction determination reference angle T ₁ is located within a set angle (eg, ± 90 °) (S309). Next, the overcurrent protection device determines that the direction discrimination reference angle T ₁ is within the set angle (eg, ± 90 °) in the forward direction (S310), and when the direction angle reference angle is outside the set angle range (S311).

Referring to FIG. 6 again, the overcurrent protection device operates the breaker when the failure direction is in the forward direction (S400).

When the failure direction is in the reverse direction, the overcurrent protection device counts the number of times that the failure direction is determined as the reverse failure (S500). Next, the overcurrent protection device determines whether the number of times determined as a reverse failure continuously occurs for a specific number or more (S600).

The overcurrent protection device operates the breaker as in the case where the failure direction is the forward direction when the number of times determined to be the reverse failure continuously occurs for a predetermined number or more.

Next, the overcurrent protection method and the method of applying the device to the control device of the circuit breaker will be described in detail with reference to FIG.

8 is a view showing the configuration and operation of the overcurrent protection method according to an embodiment of the present invention and the protection device to which the device is applied.

Referring to FIG. 8, an overcurrent protection method and apparatus according to an embodiment of the present invention may be implemented in a control device (terminal device) 820 of a circuit breaker (line recloser or substation CB) 810.

The control device 820 receives a voltage and a current from the instrument current transformer CT and the instrument transformer PT of the circuit breaker 810 to determine the direction of the failure.

The controller 820 does not send a trip signal to the breaker when the failure direction is determined to be reverse, and transmits a trip signal to the breaker only when it is determined to be in the forward direction so that the breaker operates.

In this way, when the overcurrent protection method and the device are installed in the dendritic distribution system to which the distributed power supply is connected, the protection device operates only in the self-protection section (load side based on the installation point of the protection device). In case of failure, unnecessary malfunction can be prevented.

The method for determining the fault direction of a protective device applied to a distribution system to which a distributed power source is connected according to an embodiment of the present invention is applied to an automatic switchgear for distribution automation operated in a distribution system to which a distributed power source is linked. I can tell you.

Next, a malfunction of the failure indicator of the distribution automation switch when a failure occurs in the distribution line to which the distributed power supply is connected will be described in detail with reference to FIG. 9.

FIG. 9 is a circuit diagram illustrating a distribution of fault currents when a distribution automation automation switch is operated in a distribution system in which distributed power supplies are linked.

When a line fault occurs, the automation equipment detects a line fault and displays fault information (Fault Indication (FI)) on the human machine linkage system (HMI) of the distribution automation system to inform the operator of the fault. The operator then operates the switch remotely to recover from the fault.

Automated equipment displays a fault indicator (FI) when both line no-voltage and fault currents are detected. That is, the automatic switch detects a fault current when a line break occurs and detects no voltage when there is a trip or re-closing operation of the line protection device and sends a failure indicator (FI) to the human machine linkage system of the distribution automation system. Will be displayed.

Referring to FIG. 9, when a failure occurs at a specific point F2, the automatic switchgear GA 910 detects a failure by a reverse failure current on the distributed power supply side, and the first recloser RC1 920 or When the first breaker (CB1) 930 operates, it detects no voltage and displays the failure indicator (FI) information on the distribution automation system.

Typically, the distribution automation operator in the dendritic distribution system without the distributed power supply determines the failure in the load stage of the automation switch in which the failure indicator (FI) is displayed based on the failure indicator (FI) information of the automation switch. Although a failure occurs at the (CB1) 930 and the first recloser (RC1) 920 points, there is a high possibility that a failure occurs in the load stage below the automatic switchgear (GA) 910. In this case, failure to accurately determine the point of failure occurs a problem that is likely to prolong the failure recovery failure and power outage time.

The failure indicator (FI) generation method of the automatic switchgear in the distribution system connected with the distributed power source adds a method of determining the direction of the failure in the method of displaying the failure indicator (FI) by detecting the fault current and no voltage. By providing FI) information and fault direction information, the distribution automation operator can pinpoint the fault location.

Next, a method of displaying a failure indicator by applying a method of determining a failure direction according to an embodiment of the present invention will be described in detail with reference to FIG. 10.

10 is a flowchart illustrating a method of generating a failure indicator to which a method of determining a failure direction is added according to an exemplary embodiment of the present invention.

Referring to FIG. 10, the automated switch measures voltage and current for each phase (S11). Next, the automatic switch detects a failure by comparing the measured current with a set current corresponding to the minimum operating current of the protection device (S12). Here, the automatic switch detects a failure when the measured current is greater than or equal to the set current. When detecting a failure, the automatic switch detects no voltage (S13).

When detecting no voltage, the automatic switch determines whether the failure direction is forward or reverse (S14). Specifically, the automatic switch determines the type of failure by using the reverse phase current, and determines whether the failure direction is in the forward direction or the reverse direction by using a specific determination element corresponding to the determined failure type. Here, the failure type includes an unbalance failure and an equilibrium failure, and the specific determination element includes an inverse phase direction determination element corresponding to an unbalance failure and a normal direction direction determination element corresponding to an equilibrium failure.

When the failure direction is in the forward direction, the automatic switchgear provides the failure indicator (FI) information and the forward information to the human machine linkage device (HMI) of the distribution automation system (S15).

When the failure direction is in the reverse direction, the automatic switchgear provides the failure indicator (FI) information and the reverse information to the human machine linkage device (HMI) of the distribution automation system (S16).

As described above, in implementing the method of providing the failure indicator (FI) information and the failure direction information together in the distribution automatic switchgear, a method of determining a failure direction according to an embodiment of the present invention may be applied. In addition, a method of generating a failure indicator of the distribution automation switch may be implemented in the distribution automation switch control device (terminal device).

As described above, the best embodiment has been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10; Recloser 20; Second breaker
100; Measurement unit 200; Fault detector
300; Direction determination unit 400; Breaking
310; A fundamental wave calculator 320; Output
330; Failure type determination unit 340; Direction determination unit
810; Breaker 820; Controller
910; Automatic switchgear 920; Recloser 930; First breaker

Claims (11)

In the device to protect the overcurrent generated in the distribution system to which the distributed power supply is connected,
A measuring unit measuring voltage and current for each phase;
A failure detector for detecting a failure based on a comparison result by comparing the current with a set current;
A direction determination unit for determining a type of failure and determining whether the failure direction is in the forward direction or the reverse direction by using the reverse phase direction determination element and the normal direction direction determination element for each of the determined failure types; And
Breaker to protect the over-current by operating the breaker when the fault direction is the forward direction
Overcurrent protection device comprising a. The method according to claim 1,
The direction determination unit
A fundamental wave calculator configured to extract a fundamental wave voltage and a fundamental wave current by removing harmonics of the voltage and current;
A calculator configured to calculate a normal voltage, a normal voltage, a reverse phase voltage, and a reverse phase current using the fundamental wave voltage and the fundamental wave current;
A failure type determination unit that determines whether the failure type is an unbalanced or an equilibrium failure using the reverse phase current; And
Direction determination unit for determining the failure direction by using the reverse normal direction determination element when it is determined that the unbalance failure, and the normal direction direction determination element when it is determined that the balance failure
Overcurrent protection device comprising a. The method according to claim 2,
The failure type determination unit
And an unbalance failure when the reverse phase current is greater than or equal to a set value, and an equilibrium failure when the reverse phase current is less than a set value. The method according to claim 3,
The set value of the over-current protection device corresponding to the reverse phase current when the maximum unbalance before the failure occurs in the distribution system. The method according to claim 1,
The reverse phase direction determining element includes a reverse phase voltage, a reverse phase current, and a maximum sensitivity phase angle.
And the normal direction direction determining element comprises a normal voltage, a normal current and a maximum sensitivity phase angle. The method according to claim 2,
The direction determining unit
And if it is determined that the unbalance is a failure, the direction discrimination reference angle generated using the reverse phase direction discrimination element is determined in the forward direction if it is within the set angle range, and is determined in the reverse direction if it is outside the set angle range. The method according to claim 2,
The direction determining unit
If it is determined that the equilibrium failure, the over-current protection device is determined in the forward direction if the reference angle for the direction plate generated by using the normal direction direction determination element is within the set angle, and in the reverse direction if it is outside the set angle range. In the method of protecting overcurrent generated in the distribution system to which the distributed power supply is connected,
Measuring voltage and current for each phase in the distribution system by an overcurrent protection device;
Comparing the current with a set current to detect a failure based on a comparison result;
Determining a failure type and determining a failure direction by using a reverse phase direction determination element and a normal direction direction determination element for each of the determined failure types; And
Protecting the overcurrent by operating a circuit breaker when the failure direction is in the forward direction
Overcurrent protection method comprising a. The method according to claim 8,
The determining of the failure direction
Extracting a fundamental wave voltage and a fundamental wave current by removing harmonics of the voltage and current;
Calculating a normal voltage, a normal current, a reverse phase voltage, and a reverse phase current using the fundamental wave voltage and the fundamental wave current;
Determining an unbalance failure when the reverse phase current is greater than or equal to a set value, and determining an equilibrium failure when the reverse phase current is less than a set value; And
Determining the failure direction by using the reverse phase direction determination element when it is determined that the unbalanced failure is determined, and determining the failure direction by using the normal part determination element when it is determined that the balance failure occurs.
Overcurrent protection method comprising a. The method according to claim 9,
The determining of the failure direction
Generating a direction angle reference angle using the reverse phase direction determination element when it is determined that the unbalance failure has occurred;
Determining in the forward direction if the reference angle for each direction determination is within a set angle range; And
If the reference angle for each direction plate is outside the set angle range, determining in the reverse direction
Overcurrent protection method comprising a. The method according to claim 9,
The determining of the failure direction
If it is determined that the equilibrium failure is generated, generating a direction angle reference angle using the normal direction determination element;
Determining in the forward direction if the reference angle for each direction determination is within a set angle range; And
If the reference angle for each direction plate is outside the set angle range, determining in the reverse direction
Overcurrent protection method comprising a.

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