JPH06343230A - System-interconnection protecting apparatus - Google Patents

Abstract

PURPOSE:To detect the single operation of a generator in an accident at the side of a system in a private non-utility power generating apparatus in the high-voltage distribution system interconnection by detecting the service interruption on the side of the system based on the change in impedance obtained from an impedance operating circuit. CONSTITUTION:In a system interconnection system, wherein non-utility power generating devices 1a and 1b are linked to a utility system and there is a reverse current, a higher harmonic generator 17a, which does not receive the signal from a utility substation 3 at the time of the service interruption of the an electric power system, is provided. The service interruption of the electric power system can be detected by always monitoring the higher harmonic impedance on the system side. Therefore, a receiving-point breaker 14a can be quickly separated without providing an expensive transfer cut-off device between a receiving/sending breaker 5 and the receiving-point breaker 14a for a demand house of a non-utility power generating apparatus.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system interconnection protection device in case of a system accident in a system interconnection system (commercial power line interconnection system).

[0002]

2. Description of the Related Art In general, a grid interconnection system as shown in FIG. 5 is used by a high-voltage customer for grid interconnection of private power generation equipment such as cogeneration (hereinafter referred to as private power generation equipment). That is, in the system interconnection system of FIG. 5, 1a is a private power generation facility, 2 is a system busbar, 3 is a distribution substation, 4 is a transformer, 5 is a circuit breaker, and 6 is a transfer receiving device. The transfer receiving device 6 releases the circuit breaker 14a of the in-house private power generation equipment 1a in response to a signal from the substation 3 at the time of a system fault in the case of reverse power flow. The private power generation facility 1a includes a generator 11a driven by an engine (not shown), an automatic voltage regulator (hereinafter, referred to as AVR) 12a that controls the voltage of the generator 11a, and a generator 11a in a local system. And a circuit breaker 14a connecting the system bus 2 and the premises system 10, a premises load 15a, and a premises load circuit breaker 16a, and an undervoltage relay 21a as a protection device. , Frequency reduction relay 22a, overvoltage relay 23a, overcurrent relay 24a, directional ground fault relay 25a, reverse power relay 26
a, a generator abnormality detection relay 27a. Further, 1b is a customer equipped with a private power generation facility having the same configuration as the private power generation facility 1a, and 1c is a power receiving facility without a private power generation facility (circuit breaker 14c and premises load 15c).
It is a customer equipped with only.

When the following abnormality occurs in the grid interconnection system thus configured, it is necessary to immediately disconnect the private power generation equipment 1a, 1b from the power grid. (1) In the case of a customer's premises accident with a cogeneration installation (2) In the event of a power system accident

As a method of detecting the accident state at the time of these accidents, it is usually detected by a protective relay device as shown in FIG. That is, when there is no reverse power flow, the overcurrent relay 24a, the ground fault relay 25a, the generator abnormality detection relay 2
7a, reverse power relay 26a, frequency reduction relay 22a, etc. detect an abnormality at the time of an accident in the private power generation equipment or the grid,
The circuit breaker 14a is opened to disconnect from the system. On the other hand, when there is a reverse power flow, there is a case where the above-mentioned relay or the like cannot detect the disconnection of the substation circuit breaker 14a when the system is abnormal. Therefore, the transfer breaker 6 is provided in the dedicated line interconnection for protection. Is going.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and its object is to connect a high-voltage power distribution system without providing an expensive transfer interruption device in a dedicated line connection in the case of reverse power flow. It is an object of the present invention to provide a system interconnection protection device that can detect a generator independent operation in the event of an accident on the system side in a private power generation facility in a system.

[0006]

In order to achieve the above object, a system interconnection protection device of the present invention is used in a system interconnection system in which a private power generation facility is connected to a high voltage distribution system with reverse power flow. A harmonic generator that injects a harmonic into the system bus, a current transformer that detects the harmonic current on the power receiving side, and an impedance calculation circuit that calculates the impedance on the power receiving side by the output of the current transformer, A feature is that a power failure on the system side is detected by a change in impedance obtained from the impedance calculation circuit.

[0007]

The system interconnection protection device of the present invention is made by paying attention to the fact that the system impedance changes during a power failure on the system bus side. The system impedance is constantly monitored, and when a power failure occurs, the detected impedance is detected in advance. By changing to the value set by the system impedance map, it is possible to promptly detect that a power failure has occurred in the system.

[0008]

Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 is a configuration diagram of a system interconnection protection device for an in-house power generation facility that is an embodiment of the present invention. The configuration different from the conventional system interconnection system in FIG. 5 has a harmonic generator in an in-house power generation facility 1a. Since the transfer interruption device 6 is eliminated by providing the impedance detection circuit 17a and the impedance detection circuit 18a, the same components as those of the conventional system interconnection system are designated by the same reference numerals and the description thereof is omitted.

In FIG. 1, the harmonic generator 17a and the impedance detection circuit 18a of the private power generation equipment 1a are connected to a point A on the local system bus. Reference numeral 19a is a current detecting current transformer for measuring the current on the power receiving side, and is an output of the impedance detecting circuit 18a and is a circuit breaker 14 for receiving power on the premises.
It is configured to output a cutoff command to a.

FIG. 2 is a circuit diagram of the harmonic generator 17a. In FIG. 2, reference numeral 171 is an inverter device as a harmonic generation source, which is composed of a three-phase bridge transistor inverter. Reference numeral 172 is a capacitor that is a supply source of the harmonic voltage, 173 is a transformer for injecting the harmonic wave, and 174 is a transformer for detecting the harmonic voltage, which is for returning the harmonic voltage generator. A harmonic voltage control circuit 175 controls the frequency, voltage, and phase of the harmonic voltage.

FIG. 3 shows the impedance detection circuit 18a.
181 is a transformer for detecting a harmonic voltage, 182 is a first filter circuit for detecting only a harmonic voltage component of the transformer 181, and 183 is an output of a current transformer. It is a second filter circuit for converting into a voltage and detecting only a harmonic component of the voltage. 184 and 185 are DC voltage conversion circuits that convert the harmonic components of the voltage and current into DC voltages, 186 is an impedance calculation circuit that calculates the impedance of the harmonic components from the voltage component and current component, and 187 is the calculation circuit. The output circuit operates the output relay when the output level is compared with a preset impedance value and exceeds the set value.

By the way, the impedance on the power receiving point side as seen from the point A of the injection point of the harmonic voltage of the consumer shown in FIG.
As shown in (4), the generators and loads of other consumers and the impedance of the system are connected in parallel. Here, 13b, 14b,
16b is a circuit breaker for the customer 1b, 14c is a circuit breaker for the customer 1c, and generally, in the indoor impedance Xbc (parallel impedance of XGb, XLb, XLc) and the system impedance XB of another customer, XB << Xbc Have a relationship.

The operation of the embodiment thus configured will be described below. In the grid interconnection system of the private power generation equipment according to the present embodiment of FIG.
Power is generated at a and 11b. The loads 15a and 15b may be in a so-called reverse power flow operation in which electric power is supplied from the generators 11a and 11b and the system side, or electric power is supplied from the generators 11a and 11b to the load and the system side. In the latter case of reverse power flow operation, if the harmonic voltage is injected into point A of the private power generation facility, the harmonic voltage and harmonic current from point A to the power receiving side are input to the impedance detection circuit 18a in FIG. , Impedance is calculated, but this value is naturally less than or equal to a preset value. But,
In this state, if the circuit breaker 5 on the system side opens for some reason, the impedance at the power receiving point seen from point A is only the generators and loads of other consumers, and the impedance detection value in the impedance detection circuit 18a in FIG. Change,
You will know the power failure on the grid side. Therefore, the power receiving point breaker 14a can be quickly disconnected. In addition, it does not particularly relate to the presence or absence of the harmonic generator in the private power generation equipment 1b of other customers.

[0014]

As described above, according to the present invention, in the grid interconnection system with reverse power flow in which the private power generation equipment is interconnected to the high-voltage distribution system, the signal from the distribution substation is received when the power system is interrupted. Even if you do not have a harmonic power supply on the premises,
Since it is possible to detect a power failure in the power system by constantly monitoring the harmonic impedance on the system side, an expensive transfer breaker will be installed between the breaker for sending out the incoming power line and the breaker for the private power generation facility customer The power receiving point circuit breaker can be promptly disconnected without

[Brief description of drawings]

FIG. 1 is a configuration diagram of a system interconnection protection device for a private power generation facility that is an embodiment of the present invention.

FIG. 2 is a circuit diagram of the harmonic generator of FIG.

FIG. 3 is an impedance detection circuit diagram of FIG.

FIG. 4 is an impedance circuit diagram of FIG.

FIG. 5 is a circuit diagram of a conventional system interconnection protection device for a private power generation facility.

[Explanation of symbols]

1a, 1b ... Private power generation equipment, 2 ... System busbar, 3 ... Distribution substation, 4 ... Transformer, 5 ... Circuit breaker, 6 ... Transfer receiving device,
10 ... internal system bus, 11a, 11b ... AC generator, 1
2a, 12b ... Automatic voltage regulator, 13a, 13b, 1
4a, 14b, 14c, 16a, 16b ... Circuit breaker, 15
a, 15b, 15c ... premises load, 17a ... harmonic generation circuit, 18a ... impedance detection circuit, 21a ... undervoltage relay, 22a ... frequency drop relay, 23a ... overvoltage relay, 24a ... overcurrent relay, 25a ... direction ground fault Relay, 26a ... Reverse power relay, 27a ... Generator abnormality detection relay.

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[Procedure amendment]

[Submission date] August 31, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

[Title of Invention] System interconnection protection device

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system interconnection protection device in case of a system accident in a system interconnection system (commercial power line interconnection system).

[0002]

2. Description of the Related Art Generally, a grid interconnection system as shown in FIG. 5 is used by a customer to grid-connect a private power generation facility such as cogeneration (hereinafter referred to as private power generation facility). That is, in the system interconnection system of FIG. 5, 1a is a private power generation facility, 2 is a system busbar, 3 is a distribution substation, 4 is a transformer, 5 is a receiving wire sending circuit breaker, 6
Is a transfer receiver. This transmission / reception device 6 uses a signal from the substation 3 in the event of a system fault in the case of reverse power flow, to generate power from the in-house private power generation equipment 1a
4a is released. In addition, the above-mentioned private power generation facility 1
a is a generator 1 driven by an engine (not shown)
1a, an automatic voltage regulator (hereinafter referred to as AVR) 12a that controls the voltage of the generator 11a, a circuit breaker 13a that connects the generator 11a to the premises system, and a circuit breaker that connects the system bus 2 to the premises system 10. 14a, a premises load 15a,
It has an internal load circuit breaker 16a, and further has an undervoltage relay 21a and a frequency lowering relay 2 as protection devices.
2a, an overvoltage relay 23a, an overcurrent relay 24a, a direction ground fault relay 25a, a reverse power relay 26a, and a generator abnormality detection relay 27a. Further, 1b is a customer equipped with a private power generation facility having the same configuration as the private power generation facility 1a described above, and 1c is a demand equipped with only a power receiving facility (circuit breaker 14c and premises load 15c) that does not have a private power generation facility. Home

When the following abnormality occurs in the grid interconnection system thus configured, it is necessary to immediately disconnect the private power generation equipment 1a, 1b from the power grid. (1) In the case of a customer's premises accident with a cogeneration installation (2) In the event of a power system accident

As a method of detecting the accident state at the time of these accidents, it is usually detected by a protective relay device as shown in FIG. That is, when there is no reverse power flow, the overcurrent relay 24a, the ground fault relay 25a, the generator abnormality detection relay 2
7a, reverse power relay 26a, frequency reduction relay 22a, etc. detect an abnormality at the time of an accident in the private power generation equipment or the grid,
The circuit breaker 14a is opened to disconnect from the system. On the other hand, when there is a reverse power flow, there is a case where the above-mentioned relay or the like cannot detect the disconnection of the substation circuit breaker 5 when the system is abnormal. Therefore, the transfer breaker 6 is provided for protection.

[0005]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide on-site private power generation in a distribution system interconnection without providing an expensive transfer interruption device in the case of reverse power flow. An object of the present invention is to provide a system interconnection protection device capable of detecting a generator independent operation in the case of an accident on the system side in the facility.

[0006]

In order to achieve the above object, a system interconnection protection device of the present invention is a system interconnection system in which an in-house power generation system is connected to a distribution system with a reverse power flow, and a local system busbar is provided. A harmonic generator for injecting harmonics into
A current transformer that detects a harmonic current on the power receiving side and an impedance calculation circuit that calculates the impedance on the power receiving side by the output of the current transformer, and a power failure on the system side due to a change in impedance obtained from the impedance calculation circuit. Is detected.

[0007]

The system interconnection protection device of the present invention is made by paying attention to the fact that the system impedance changes during a power failure on the system bus side. The system impedance is constantly monitored, and when a power failure occurs, the detected impedance is detected in advance. By changing to the value set by the system impedance map, it is possible to promptly detect that a power failure has occurred in the system.

[0008]

Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 is a configuration diagram of a system interconnection protection device for an in-house power generation facility that is an embodiment of the present invention. The configuration different from the conventional system interconnection system in FIG. 5 has a harmonic generator in an in-house power generation facility 1a. 17a and the impedance detection circuit 18a are provided to abolish the transfer interruption device 6 and the reverse power relay 26a is abolished because of reverse power flow. Therefore, the same components as those of the conventional system interconnection system are designated by the same reference numerals. The description is omitted.

In FIG. 1, the harmonic generator 17a and the impedance detection circuit 18a of the private power generation equipment 1a are connected to a point A on the local system bus. Reference numeral 19a is a current detecting current transformer for measuring the current on the power receiving side, and is an output of the impedance detecting circuit 18a and is a circuit breaker 14 for receiving power on the premises.
It is configured to output a cutoff command to a.

FIG. 2 is a circuit diagram of the harmonic generator 17a. In FIG. 2, reference numeral 171 is an inverter device as a harmonic generation source, which is composed of a three-phase bridge transistor inverter. Reference numeral 172 is a capacitor that is a supply source of the harmonic voltage, 173 is a transformer for injecting the harmonic wave, and 174 is a transformer for detecting the harmonic voltage, which is for returning the harmonic voltage generator. A harmonic voltage control circuit 175 controls the frequency, voltage, and phase of the harmonic voltage.

FIG. 3 shows the impedance detection circuit 18a.
181 is a transformer for detecting a harmonic voltage, 182 is a first filter circuit for detecting only a harmonic voltage component of the transformer 181, and 183 is an output of a current transformer. It is a second filter circuit for converting into a voltage and detecting only a harmonic component of the voltage. 184 and 185 are DC voltage conversion circuits that convert the harmonic components of the voltage and current into DC voltages, 186 is an impedance calculation circuit that calculates the impedance of the harmonic components from the voltage component and current component, and 187 is the calculation circuit. The output circuit operates the output relay when the output level is compared with a preset impedance value and exceeds the set value.

By the way, the impedance on the power receiving point side as seen from the point A of the injection point of the harmonic voltage of the consumer shown in FIG.
As shown in (4), the generators and loads of other consumers and the impedance of the system are connected in parallel. Here, 13b, 14b,
16b is a circuit breaker for the customer 1b, 14c is a circuit breaker for the customer 1c, and generally, in the indoor impedance Xbc (parallel impedance of XGb, XLb, XLc) and the system impedance XB of another customer, XB << Xbc Have a relationship.

The operation of the embodiment thus configured will be described below. In the system interconnection system of the private power generation equipment according to the present embodiment of FIG. 1, the in-house private power generation equipment 1a and the in-house private power generation equipment 1b of other customers are supplied with electric power from the commercial grid side, or Reverse power operation is performed, in which surplus power is sent from the power generation equipment to the commercial grid side. In the latter case of reverse power flow operation, if the harmonic voltage is injected into point A of the private power generation equipment, the harmonic voltage and harmonic current from point A to the power receiving side are detected by the impedance detection circuit 18a in FIG.
Is input to calculate the impedance, but this value is naturally less than or equal to a preset value. However, if the circuit breaker 5 on the system side is opened for some reason in this state, the impedance of the power receiving point seen from point A is only the generators and loads of other consumers, and the impedance detection circuit 18a in FIG. 3 detects the impedance. The value changes, and the power failure on the grid side is known. Therefore, the receiving point breaker 14
a can be separated. In addition, it does not particularly relate to the presence or absence of the harmonic generator in the private power generation equipment 1b of other customers.

[0014]

As described above, according to the present invention, in the grid interconnection system with reverse power flow in which the private power generation equipment is interconnected to the distribution grid, the signal from the distribution substation is not received at the time of power grid interruption. Even if a harmonic power supply is installed on the premises and a power system power failure can be detected by constantly monitoring the harmonic impedance on the grid side, it can be used as a feeder breaker and a private power generation facility customer receiving point breaker. It is possible to quickly disconnect the power receiving point breaker without providing an expensive transfer breaker between them.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a system interconnection protection device for a private power generation facility that is an embodiment of the present invention.

FIG. 2 is a circuit diagram of the harmonic generator of FIG.

FIG. 3 is an impedance detection circuit diagram of FIG.

FIG. 4 is an impedance circuit diagram of FIG.

FIG. 5 is a circuit diagram of a conventional system interconnection protection device for a private power generation facility.

[Explanation of Codes] 1a, 1b ... Private power generation facility, 2 ... System busbar, 3 ... Distribution substation, 4 ... Transformer, 5 ... Receiving wire feeding breaker, 6 ...
Transfer receiving device, 10 ... Premises system busbar, 11a ... AC generator, 12a ... Automatic voltage adjusting device, 14a ... Private power generation facility customer breaker, 14b ... Power receiving point breaker, 13a, 13
b, 14c, 16a, 16b ... Circuit breaker, 15a, 15c
... premises load, 17a ... harmonic generation circuit, 18a ... impedance detection circuit, 21a ... undervoltage relay, 22a ...
Frequency lowering relay, 23a ... Overvoltage relay, 24a ... Overcurrent relay, 25a ... Direction ground fault relay, 26a ... Reverse power relay, 27a ... Generator abnormality detection relay.

[Procedure Amendment 2]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 1

[Correction method] Change

[Correction content]

[Figure 1]

Claims (1)

[Claims] 1. In a system interconnection system in which private power generation equipment is connected to a high-voltage distribution system with reverse power flow, a harmonic generator that injects harmonics into a local system bus and a harmonic current on the power receiving side is detected. A current transformer, and an impedance calculation circuit that calculates the impedance of the power receiving side by the output of the current transformer, the power failure of the system side is detected by the change in impedance obtained from the impedance calculation circuit. Characteristic system interconnection protection device.