KR102008150B1 - Decentralized power control apparatus - Google Patents

Abstract

Embodiments include a collection unit for receiving a voltage provided from the distributed power source to the linkage point, a current provided to the linkage point in the power system, and load impedance information between the linkage point and the power system; A calculation unit configured to calculate an effective power consumed by the distributed power supply using the voltage provided from the distributed power supply to the linking point and the current provided from the power system to the linking point; A determination unit outputting a first determination signal when the effective power consumed by the distributed power is positive; And an output unit configured to generate an output signal for opening the connection point breaker when the first determination signal is output.

Description

Distributed Power Control Unit {DECENTRALIZED POWER CONTROL APPARATUS}

Embodiments relate to a distributed power supply control device.

When the demand for power increases rapidly, existing centralized power generation systems such as hydroelectric, thermal, and nuclear power generation are not only able to cope with power demand quickly and efficiently, but also have environmental pollution.

Therefore, in recent years, the development of a distributed power supply system based on renewable energy has been actively made, and widely used and used.

The distributed power source of the distribution power system is to reduce the energy transmission and transmission and distribution facilities by installing power generation facilities such as photovoltaic power generation, fuel cell power generation, and wind power generation near energy consumers or in buildings.

In addition, in accordance with the development of communication technology, distributed power generation is being implemented in economical scale through remote automatic operation.

When a plurality of distributed power sources are installed in the distribution power system to transmit the distributed power output to the distribution power system, the distribution power system may be supplied with the generation amount of the distributed power supply. However, when energy generation is difficult in a distributed power source, a problem arises in that power is consumed by consuming power from a distribution power system. For this reason, there is a problem in that a power generation such as a power generation facility in which distributed power generation is installed reduces revenue due to power consumption. In addition, when the distributed power supply alone operates, there is a limit in which a safety threat occurs such as an electric shock or the like occurring to a line operator.

Embodiments provide a distributed power supply control device for improving power efficiency.

In addition, it provides a distributed power supply control device to ensure the safety of the line operator.

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

In one embodiment, a distributed power supply control device includes a collection unit configured to receive a voltage provided from a distributed power source to an associated point, a current provided to the associated point in a power system, and load impedance information between the associated point and the power system; A calculation unit configured to calculate an effective power consumed by the distributed power supply using the voltage provided from the distributed power supply to the linking point and the current provided from the power system to the linking point; A determination unit outputting a first determination signal when the effective power consumed by the distributed power is positive; And an output unit configured to generate an output signal for opening the connection point breaker when the first determination signal is output.

The calculation unit,

From the distributed power supply and the voltage provided from the power system using the voltage provided from the distributed power supply to the linking point and the current provided to the linking point in the power system and the load impedance information between the linking point and the power system from the distributed power supply The phase difference angle between the voltages to be calculated can be calculated.

The determination unit,

The second determination signal may be output by comparing a change rate of a phase difference angle between a voltage provided from the power system and a voltage provided from the distributed power supply and a preset change rate.

The output unit may include an output unit configured to generate an output signal for inputting the link breaker when the second determination signal is output.

The effective power consumed by the distributed power supply may be calculated by Equation 1 below.

[Equation 1]

는 전력 계통에서 연계점으로 제공되는 전류 크기이고,

는 분산 전원으로부터 연계점에 제공되는 전압의 크기이고,

는 전력 계통에서 연계점으로 제공되는 전류 위상이다)Where P is the active power consumed by distributed power,

Is the amount of current provided to the junction in the power system,

Is the magnitude of the voltage provided from the distributed source to the junction.

Is the current phase provided to the junction in the power system)

The phase difference angle between the voltage provided from the power system and the voltage provided from the distributed power supply may be calculated by Equation 2 below.

[Equation 2]

는 전력 계통으로부터 제공되는 전압과 분산 전원으로부터 제공되는 전압 사이의 상차각이고,

은 연계점과 전력 계통 사이의 부하 임피던스의 저항값이고,

은 연계점과 전력 계통 사이의 부하 임피던스의 리액턴스값이고,

은 전력 계통에서 연계점으로 제공되는 전류 위상이고,

는 전력 계통에서 연계점으로 제공되는 전류의 위상이 0보다 크면 1이고, 0보다 작으면 -1이고,

는 전력 계통으로부터 제공되는 전압 크기이다)(here,

Is the phase difference angle between the voltage provided from the power system and the voltage provided from the distributed power supply,

Is the resistance of the load impedance between the junction and the power system,

Is the reactance value of the load impedance between the junction and the power system,

Is the current phase provided to the junction in the power system,

Is 1 if the phase of the current provided to the junction in the power system is greater than 0, -1 if less than 0,

Is the magnitude of the voltage provided by the power system)

The link point breaker may be disposed between the link point and the distributed power supply.

Distributed power supply control system according to an embodiment includes a power system; Distributed power supply; An interconnection point disposed between the power system and the distributed power supply to connect the power system and the distributed power supply; An association point breaker disposed between the association point and the distributed power supply; And a distributed power supply control device, wherein the distributed power supply control device includes a voltage provided from the distributed power supply to the connection point, a current provided to the connection point in a power system, and a load between the connection point and the power system. Collecting unit for receiving the impedance information; A calculation unit configured to calculate an effective power consumed by the distributed power supply using the voltage provided from the distributed power supply to the linking point and the current provided from the power system to the linking point; A determination unit outputting a first determination signal when the effective power consumed by the distributed power is positive; And an output unit configured to generate an output signal for opening the connection point breaker when the first determination signal is output.

According to the embodiment, it is possible to implement a distributed power supply control device for improving power efficiency.

In addition, it is possible to manufacture a distributed power supply control device to ensure the safety of the line operator.

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

1 is a conceptual diagram of a distributed power supply control system according to an embodiment;
2 is a block diagram of a distributed power supply control apparatus according to the embodiment,
3 is an equivalent circuit diagram of a distributed power supply control system,
4 and 5 are phasor diagrams for calculating a phase difference angle between the distributed power supply voltage and the voltage of the power system during the ground operation and the advance operation of the distributed power supply, respectively.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated and described in the drawings. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

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

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may be present in between. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings, and the same or corresponding components will be given the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted.

1 is a conceptual diagram of a distributed power supply control system according to an embodiment.

Referring to FIG. 1, a distributed power supply control system 10 according to an embodiment may include a power system 11, a distributed power supply 12, an interconnection point P, a distributed power supply control device 13, and an interconnection point breaker 14. , Line 15 and load 16.

First, the power system 11 may supply power to the load 16. The power system 11 includes power generation equipment on the power plant side, and may include a bank of a substation for power distribution, but is not limited thereto.

The distributed power supply 12 supplies power to the load 16 as described above, but may be connected in parallel to the power system 11. The distributed power supply 12 supplies power generated by various energy sources, and includes fuel consumption systems such as gas turbines, gas engines, diesel engines, natural energy systems such as wind power, hydropower, solar power, etc. according to energy sources. And it can be divided into unused energy system such as waste power generation. However, it is not limited to this kind.

The distributed power supply 12 is installed adjacent to the load 16, which is a demand destination, to reduce power loss due to power transmission. In addition, the distributed power supply 12 is electrically connected to the power system 11 and the load 16 through the link point (P), when a system failure occurs between the power system 11 and the link point (P) The power supply to the load 16 can be maintained. In addition, the distributed power supply 12 may be a plurality, but is not limited thereto.

The link point P may be disposed between the power system 11 and the distributed power supply 12. As described above, the connection point P may be a point connecting the distributed power supply 12 and the grid for supplying power in parallel to the grid supplied from the power grid 11 to the load 16. There may be a plurality of link points P depending on the number of distributed power supplies 12, but is not limited thereto.

The distributed power supply control device 13 may generate an output signal for controlling the opening or closing of the connection point breaker 14. The distributed power supply control device 13 may transmit the output signal to the link point breaker 14 to control whether the distributed power supply 12 is supplied to the demand site in parallel through the link point P. A detailed description of the distributed power supply control device 13 will be described later with reference to FIG. 2.

The link point breaker 14 may be disposed between the link point P and the distributed power supply 12. The link point breaker 14 may control whether the power supplied from the distributed power supply 12 to the load 16 through the link point P is supplied. For example, when an output signal for inputting the link point breaker 14 from the distributed power supply control device 13 is provided to the link point breaker 14, the link point breaker 14 is, for example, a distributed power supply in an electrical short state. 12 and the load 16 can be electrically connected. In addition, the distributed power supply 12 may supply power to the load 16 through the link point P.

In addition, when an output signal for opening the linkage breaker 14 from the distributed power supply control device 13 is provided to the linkage breaker 14, the linkage breaker 14 is, for example, in the electrical open state. The electrical connection between 12) and the load 16 may be interrupted. Therefore, the distributed power supply 12 may not supply power to the load 16 through the link point (P).

Accordingly, the connection point breaker 14 may include a circuit breaker (CB), but is not limited thereto.

And the load 16 may be connected to the link point (P). In addition, the load 16 may receive power from the power system 11 or the distributed power supply 12 through the link point P. The load 16 may include a home, a building, and the like as a consumer consuming power, but is not limited thereto.

2 is a block diagram of a distributed power supply control apparatus according to an embodiment, FIG. 3 is a diagram illustrating an equivalent circuit diagram of a distributed power supply control system, and FIGS. 4 and 5 are distributed power supplies during ground operation and advance operation of the distributed power supplies, respectively. A phasor diagram for calculating the phase difference between voltages and voltages in the power system.

2 to 5, the distributed power supply control apparatus according to the embodiment may include a collector 110, a calculator 120, a determiner 130, an output 140, and a communicator 150. .

First, the collection unit 110 is a voltage provided from the distributed power supply 12 to the link point (P), the current provided from the power system 11 to the link point (P) and the link point (P) and the power system 11 Load impedance information) can be received. Here, the voltage provided from the distributed power supply 12 to the link point P and the current provided from the power system 11 to the link point P may be values measured from a current sensor and a voltage sensor at the link point P. However, the present invention is not limited thereto.

The load impedance information between the link point P and the power system 11 may be an impedance of a line disposed between the power system 11 and the link point. For example, the impedance information may be divided into a resistance component and a reactance component of the line. The load impedance information between the link point P and the power system 11 may be received from an instrument disposed on the line.

The calculating unit 120 may include a first calculating unit and a second calculating unit.

First, the first calculating unit uses the voltage provided from the distributed power supply 12 to the link point P and the current provided from the power system 11 to the link point P. The power can be calculated.

이고, 전력 계통(11)에서 연계점(P)으로 흐르는 선로 전류(

)는

을 만족하고, 분산 전원(12)으로부터 제공되는 전압은

이고, 분산 전원(12)으로부터 연계점(P)으로 제공되는 전류(

)는

을 만족하고, 선로의 임피던스 정보는

이다. 여기서,

은 임피던스 정보의 실수로 임피던스의 저항값이고,

는 임피던스 정보의 허수로 임피던스의 리액턴스값이다. 그리고 도 3 내지 도 5에서 분산 잔원으로부터 연계점에 제공되는 전압을 기준으로 설명하는 바 위상은 0이다. 또한, 부하에 대한 영향을 제거한다.First, the voltage provided from the power system 11 in FIGS.

And the line current flowing from the power system 11 to the connection point P (

)

, The voltage supplied from the distributed power supply 12

And the current provided from the distributed power supply 12 to the connection point P

)

And the impedance information of the line is

to be. here,

Is the resistance value of the impedance by mistake of the impedance information,

Is the imaginary number of impedance information and is the reactance value of the impedance. 3 to 5, the phase is 0 based on the voltage provided from the dispersion source to the link point. It also eliminates the effect on load.

The first calculator may calculate the active power consumed by the distributed power supply 12 according to Equation 1.

는 전력 계통(11)에서 연계점(P)으로 제공되는 전류 크기이고,

는 분산 전원(12)으로부터 연계점(P)에 제공되는 전압의 크기이고,

는 전력 계통(11)에서 연계점(P)으로 제공되는 전류 위상이다)Where P is the active power consumed by the distributed power supply 12,

Is the magnitude of the current provided to the junction point P in the power system 11,

Is the magnitude of the voltage provided from the distributed power supply 12 to the link point P,

Is the current phase provided by the power system 11 to the link point P)

도 설명될 수 있다. 이에 따라, 분산 전원(12)으로부터 제공되는 전압이 소정의 값을 가지는 경우 다르게 적용될 수 있다.The second calculating section loads between the power system 11 and the current provided from the distributed power supply 12 to the link point P and the current and link point P provided from the power system 11 to the link point P. The impedance information may be used to calculate a phase difference angle between the voltage provided from the power system 11 and the voltage provided from the distributed power supply 12. For example, the phase difference angle may be calculated using the magnitude of the voltage provided from the power system 11. As described above, since the voltage provided from the distributed power supply 12 is used as the reference pager,

Can also be described. Accordingly, when the voltage provided from the distributed power supply 12 has a predetermined value, it may be differently applied.

Accordingly, the magnitude of the voltage provided from the power system 11 may be calculated by Equation 2 below.

이고, 전력 계통(11)에서 연계점(P)으로 흐르는 선로 전류(

)는

을 만족하고, 분산 전원(12)으로부터 제공되는 전압은

이고, 분산 전원(12)으로부터 연계점(P)으로 제공되는 전류(

)는

을 만족하고, 선로의 임피던스 정보는

이다. 여기서,

은 임피던스 정보의 실수로 임피던스의 저항값이고,

는 임피던스 정보의 허수로 임피던스의 리액턴스값이다)(Here, the voltage provided from the power system 11 is

And the line current flowing from the power system 11 to the connection point P (

)

, The voltage supplied from the distributed power supply 12

And the current provided from the distributed power supply 12 to the connection point P

)

And the impedance information of the line is

to be. here,

Is the resistance value of the impedance by mistake of the impedance information,

Is the imaginary number of impedance information and is the reactance value of impedance)

The phase difference may be calculated by Equation 3 below.

는 전력 계통(11)으로부터 제공되는 전압과 분산 전원(12)으로부터 제공되는 전압 사이의 상차각이고,

은 연계점(P)과 전력 계통(11) 사이의 부하 임피던스의 저항값이고,

은 연계점(P)과 전력 계통(11) 사이의 부하 임피던스의 리액턴스값이고,

은 전력 계통(11)에서 연계점(P)으로 제공되는 전류 위상이고,

는 전력 계통(11)에서 연계점(P)으로 제공되는 전류의 위상이 0보다 크면 1이고, 0보다 작으면 -1이고,

는 전력 계통(11)으로부터 제공되는 전압 크기이다)(here,

Is the phase difference angle between the voltage provided from the power system 11 and the voltage provided from the distributed power supply 12,

Is the resistance value of the load impedance between the link point P and the power system 11,

Is the reactance value of the load impedance between the link point P and the power system 11,

Is the current phase provided by the power system 11 to the junction point P,

Is 1 if the phase of the current provided from the power system 11 to the link point P is greater than 0, -1 if less than 0,

Is the magnitude of the voltage provided from the power system 11)

The determination unit 130 may output a determination signal for determining whether the connection point breaker is open or closed. For example, the determination unit 130 may output the first determination signal and the second determination signal.

The determination unit 130 may output the first determination signal when the effective power consumed by the distributed power supply 12 is positive. That is, the determination unit 130 may output the first determination signal when the effective power consumed by the distributed power supply 12 calculated by the first operation unit is greater than zero. If the effective power consumed by the distributed power supply 12 is positive, the power supplied by the distributed power supply 12 is negative, meaning that the distributed power supply 12 is in a standby power consumption state that consumes power. By such a configuration, the distributed power supply control apparatus according to the embodiment may detect a standby power consumption state generated by the distributed power supply 12 in a time when power generation is impossible, and cut off the connection between the distributed power supply 12 and the system. As a result, unnecessary power consumption can be blocked. In addition, the power consumption of the distributed power supply 12 may be improved by reducing power consumption of the distributed power supply 12.

The determination unit 130 may output a second determination signal by comparing a change rate of a phase difference angle between a voltage provided from the power system 11 and a voltage provided from the distributed power supply 12 and a preset change rate.

For example, the phase difference angle may be calculated by the calculator 120 at predetermined time intervals. In this case, the calculator 120 may calculate a rate of change of the phase difference angle at predetermined time intervals.

In addition, the determination unit 130 compares the change rate of the phase difference angle with the preset change rate, when the change rate of the phase difference angle is larger than the preset change rate, the failure of the line disposed between the power system 11 and the connection point (P) or The second determination signal, which is an output signal for the power-free transmission state (interruption), may be output according to whether the switch installed on the line is opened or the failure of the power system 11 occurs. When a failure occurs in the line, the current flowing in the line may change larger than the predetermined rate of change. For example, the failure of a line may include various line failures such as line short, open, ground fault, and the like. In addition, when the switch disposed on the track is opened, the rate of change of the phase difference angle may be increased, such as the opening of the track. Even when the power provided from the power system 11 becomes zero due to the power failure of the power system 11, the rate of change of the superimposition value may increase.

The output unit 140 may generate an output signal for opening the connection point breaker when the first determination signal is output from the determination unit 130. With this configuration, it is possible to prevent the consumption of power generated from the distributed power supply 12 as described above.

In addition, when the second determination signal is output from the determination unit 130, the output unit 140 may generate an output signal for inputting the connection point breaker. By such a configuration, the distributed power supply control apparatus according to the embodiment determines a line failure, a switch opener, a failure of the power system 11 and the like through the rate of change of the phase difference angle, so that the power provided from the distributed power supply 12 is connected to the connection point ( P) can be supplied in parallel to the system. In this way, it is possible to maintain the power supply to the customer even in the event of a system failure.

The communication unit 150 may transmit the first determination signal and the second determination signal output from the determination unit 130 to the link point breaker. According to the determination signal, the connection point breaker may perform the closing or opening operation.

In addition, when transmitting the second determination signal to the link breaker, the communication unit 150 may transmit information about the input to the server. For example, even when a failure of the power system 11 or the like, as power is supplied from the distributed power supply 12 to the connection point P (which means 'single operation'), an operator who reads or repairs a line failure is a distributed power supply. Electric power provided from (12) may be exposed to an accident such as an electric shock. Accordingly, the communication unit 150 may prevent a worker from electric shock by sending a message about the input to the server. Here, the server may be a system management server that communicates with the worker or the worker, but is not limited thereto.

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

Although the above description has been made based on the embodiments, these are merely examples and are not intended to limit the present invention. Those skilled in the art to which the present invention pertains may not have been exemplified above without departing from the essential characteristics of the present embodiments. It will be appreciated that many variations and applications are possible. For example, each component specifically shown in the embodiment can be modified. And differences relating to such modifications and applications will have to be construed as being included in the scope of the invention defined in the appended claims.

Claims (8)

A collection unit for receiving a voltage provided from the distributed power supply to the linking point, a current provided to the linking point in the power system, and load impedance information between the linking point and the power system;
A calculation unit configured to calculate an effective power consumed by the distributed power supply using the voltage provided from the distributed power supply to the linking point and the current provided from the power system to the linking point;
A determination unit outputting a first determination signal when the effective power consumed by the distributed power is positive; And
And an output unit configured to generate an output signal for opening the associated point breaker when the first determination signal is output.
The calculation unit,
From the distributed power supply and the voltage provided from the power system using the voltage provided from the distributed power supply to the linking point and the current provided to the linking point in the power system and the load impedance information between the linking point and the power system from the distributed power supply Calculate the phase difference between the voltage
The determination unit,
Distributed power supply control device for outputting a second determination signal by comparing the change rate of the phase difference angle between the voltage provided from the power system and the voltage provided from the distributed power supply and a predetermined change rate.
The method of claim 1,
The link point breaker is disposed between the link point and the distributed power supply, distributed power control device for controlling whether the power supplied through the link point.
delete The method of claim 1,
And an output unit configured to generate an output signal for inputting the connection point breaker when the second determination signal is output.
The method of claim 1,
The distributed power supply control device, the effective power consumed by the distributed power is calculated by the following equation.
[Equation 1]

Where P is the active power consumed by distributed power,

Is the amount of current provided to the junction in the power system,

Is the magnitude of the voltage provided from the distributed source to the junction.

Is the current phase provided to the junction in the power system)
The method of claim 1,
The distributed power supply control device, wherein a phase difference angle between the voltage provided from the power system and the voltage provided from the distributed power supply is calculated by Equation 2 below.
[Equation 2]

(here,

Is the phase difference angle between the voltage provided from the power system and the voltage provided from the distributed power supply,

Is the resistance of the load impedance between the junction and the power system,

Is the reactance value of the load impedance between the junction and the power system,

Is the current phase provided to the junction in the power system,

Is 1 if the phase of the current provided to the junction in the power system is greater than 0, -1 if less than 0,

Is the magnitude of the voltage provided by the power system)
The method of claim 1,
The link point breaker is disposed between the link point and the distributed power supply.
Power system;
Distributed power supply;
An interconnection point disposed between the power system and the distributed power supply to connect the power system and the distributed power supply;
An association point breaker disposed between the association point and the distributed power supply; And
Distributed power supply control device;
The distributed power supply control device,
A collector configured to receive a voltage provided from the distributed power supply to the linking point, a current provided to the linking point in a power system, and load impedance information between the linking point and the power system;
A calculation unit configured to calculate an effective power consumed by the distributed power supply using the voltage provided from the distributed power supply to the linking point and the current provided from the power system to the linking point;
A determination unit outputting a first determination signal when the effective power consumed by the distributed power is positive; And
And an output unit configured to generate an output signal for opening the connection point breaker when the first determination signal is output.
The calculation unit,
From the distributed power supply and the voltage provided from the power system using the voltage provided from the distributed power supply to the linking point and the current provided to the linking point in the power system and the load impedance information between the linking point and the power system Calculate the phase difference between the voltage
The determination unit,
And a change rate of a phase difference angle between a voltage provided from the power system and a voltage provided from the distributed power supply and a predetermined change rate, and output a second determination signal.

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