KR102559561B1 - Frequency adjustment system of photovoltaic generater using output power control - Google Patents

Abstract

A frequency adjustment system according to an embodiment of the present invention performs a first frequency adjustment based on frequency droop control and frequency change rate control so that a power system frequency measurement value enters a target frequency range A first output command value configured to calculate a first frequency adjustment module; a second frequency adjustment module configured to designate a target power system frequency recovery rate and calculate a second output command value by performing second frequency adjustment based on the designated target power system frequency recovery rate; and a generator output control module configured to increase the output of the photovoltaic generator according to the first output command value or the second output command value.

Description

Frequency adjustment system using output control of photovoltaic generator {FREQUENCY ADJUSTMENT SYSTEM OF PHOTOVOLTAIC GENERATER USING OUTPUT POWER CONTROL}

The present invention relates to a frequency adjustment system using output control of a photovoltaic generator.

In the case of a power system including a photovoltaic generator, a large frequency fluctuation may occur due to excessive supply of power due to a change in insolation even in a normal operation state of the power system.

When such a frequency fluctuation occurs, control of the amount of power generated by other generators in the power system or a separation operation to protect the photovoltaic generator is required, which harms stable power supply.

Accordingly, in order to stably operate the power system, in a power system with a high proportion of photovoltaic generators, maximum power point tracking (MPPT) for the photovoltaic generator is not performed, and constant power is output according to the control of the operator of the power system. Output control is required.

In the case of the conventional frequency control method of a photovoltaic generator, virtual inertia control (VIC), frequency droop control (FDC) and frequency change of frequency control (Rate Of Change Of Frequency, ROCOF) of DC link voltage using ESS (Energy Storage System).

However, these existing methods only contribute to the primary frequency adjustment (first frequency adjustment) at the moment when the frequency fluctuates rapidly after the event occurs when an event (excessive supply of power due to a change in solar radiation) occurs in the photovoltaic generator. It has a disadvantage that it does not contribute to the secondary frequency adjustment (second frequency adjustment) after the frequency is stabilized.

Republic of Korea Patent Publication No. 10-2020-0144410

In one embodiment of the present invention, when the stabilized frequency after the first frequency adjustment does not reach the AGC (Automatic Generation Control) operating range, a certain amount of output from the photovoltaic generator based on the target power system frequency recovery rate ( ) for a certain period of time ( It is an object of the present invention to provide a frequency adjustment system using output control of a photovoltaic generator, in which additional frequency adjustment is possible so that the frequency can return within the AGC operating range through the second frequency adjustment, which is increased during and then reduced to the original output.

On the other hand, the technical problems to be achieved in the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

A frequency adjustment system according to an embodiment of the present invention performs a first frequency adjustment based on frequency droop control and frequency change rate control so that a power system frequency measurement value enters a target frequency range A first output command value configured to calculate a first frequency adjustment module; a second frequency adjustment module configured to designate a target power system frequency recovery rate and calculate a second output command value by performing second frequency adjustment based on the designated target power system frequency recovery rate; and a generator output control module configured to increase the output of the photovoltaic generator according to the first output command value or the second output command value.

The second frequency adjustment module: calculates a second output command value for the power system frequency measurement value to enter the target frequency range by designating a target power system frequency recovery rate and performing second frequency adjustment based on the designated target power system frequency recovery rate when the stabilization frequency, which is the power system frequency measurement value after a predetermined time has elapsed, does not enter the target frequency range despite the first frequency adjustment, and the generator output control module: controls the output of the photovoltaic generator according to the second output command value for a preset time can be configured to increase for a period of time and then decrease to the original output.

The first frequency adjustment module includes: a frequency droop control output command value calculator configured to calculate a frequency droop control output command value based on a frequency droop control gain value, a power system frequency measurement value, and a rated frequency; a frequency change rate control output command value calculation unit configured to calculate a frequency change rate control output command value based on a frequency change rate control gain value, a power system frequency measurement value, and a power system frequency measurement value recovery rate; and a first output command value calculator configured to calculate a first output command value based on the output control value, the frequency droop control output command value, and the frequency change rate control output command value.

The second frequency adjustment module: specifies a target power system frequency recovery rate, and specifies the target power system frequency recovery rate, the total inertia constant of the power system, and the angular velocity of the photovoltaic generator at the rated frequency. An entire power system required power calculation unit configured to calculate a required power of the entire power system based on; an additional output command value calculation unit configured to calculate an additional output command value based on the required power of the entire power system, the capacity of the entire power system, and the capacity of the photovoltaic generator; and a second output command value calculator configured to calculate a second output command value based on the first output command value and the additional output command value.

The frequency droop control output command value calculation unit calculates a frequency droop control output command value through [Equation 1] below, and [Equation 1] , Is the frequency droop control output command value, Is the frequency droop control gain value, is the power system frequency measurement value, may be the rated frequency.

The frequency change rate control output command value calculator: calculates the frequency change rate control output command value through [Equation 2] below, and [Equation 2] , Is the frequency change rate control output command value, Is the frequency change rate control gain value, is the power system frequency measurement value, May be the power system frequency measurement value recovery rate.

The first output command value calculator: calculates the first output command value through [Equation 3] below, and [Equation 3] , Is the first output command value, is the output control value, Is the frequency droop control output command value, may be a frequency change rate control output command value.

The entire power system required output calculation unit: Calculate the total required power of the power system through [Equation 4] below, and [Equation 4] , is the required output of the entire power system, is the power system overall inertia constant, is the angular velocity of the photovoltaic generator at the rated frequency, may be a target power system frequency recovery rate.

The additional output command value calculation unit: calculates the additional output command value through [Equation 5] below, and [Equation 5] , is the additional output command value, is the required output of the entire power system, is the total installed capacity of the power system, may be the photovoltaic generator capacity.

The second output command value calculator: calculates the second output command value through [Equation 6] below, and [Equation 6] , Is the second output command value, Is the first output command value, may be an additional output command value.

In the frequency adjustment system using output control of a solar generator according to an embodiment of the present invention, when the stabilized frequency after the first frequency adjustment does not reach the AGC (Automatic Generation Control) operating range, a certain amount of output from the solar generator based on the target power system frequency recovery rate ( ) for a certain period of time ( ), additional frequency adjustment may be performed so that the frequency returns within the AGC operating range through the second frequency adjustment in which the frequency is increased and then reduced to the original output.

On the other hand, the effects obtainable in the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 shows a PV curve of a typical solar power generator.
2 is a block diagram of a first frequency adjustment module 100 according to an embodiment of the present invention.
3 is a graph showing how the output of a photovoltaic generator is controlled according to time in the second frequency adjustment process through the second frequency adjustment module 200 and the generator output control module 300 according to an embodiment of the present invention.
4 is a block diagram of a first frequency adjustment module 100 and a second frequency adjustment module 200 according to an embodiment of the present invention.
5 is a graph showing the output of a photovoltaic generator to which the frequency adjustment system 10 according to an embodiment of the present invention is applied.
6 is a graph showing the frequency of a photovoltaic generator to which the frequency adjustment system 10 according to an embodiment of the present invention is applied.

Other advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only this embodiment is provided to complete the disclosure of the present invention and to fully inform those skilled in the art of the scope of the invention to which the present invention belongs, and the present invention is only defined by the scope of the claims.

Even if not defined, all terms (including technical or scientific terms) used herein have the same meaning as generally accepted by common technology in the prior art to which this invention belongs.

Terms defined by general dictionaries may be construed to have the same meaning as they have in the related art and/or the text of this application, and are not to be construed as conceptual or overly formal, even if not expressly defined herein.

Terms used in this specification are for describing embodiments and are not intended to limit the present invention. In this specification, singular forms also include plural forms unless specifically stated otherwise in a phrase.

As used herein, 'comprise' and/or various conjugations of the verb, e.g., 'comprise', 'comprising', 'comprising', 'comprising', etc. do not exclude the presence or addition of one or more other compositions, components, components, steps, operations and/or elements in a referenced composition, component, component, step, operation and/or element. In this specification, the term 'and/or' refers to each of the listed elements or various combinations thereof.

Meanwhile, terms such as '~unit', '~group', '~block', and '~module' used throughout this specification may mean a unit that processes at least one function or operation. For example, it can mean software, hardware components such as FPGAs or ASICs.

However, '~ unit', '~ group', '~ block', '~ module', etc. are not meant to be limited to software or hardware. '~unit', '~group', '~block', '~module' may be configured to be in an addressable storage medium or configured to reproduce one or more processors.

Thus, as an example, '~unit', '~group', '~block', and '~module' include components such as software components, object-oriented software components, class components, and task components, processes, functions, properties, procedures, subroutines, segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables.

Components and functions provided within '~units', '~groups', '~blocks', and '~modules' may be combined into smaller numbers of components and '~units', '~units', '~blocks', and '~modules', or may be further separated into additional components and '~units', '~groups', '~blocks', and '~modules'.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings of this specification.

1 shows a P-V curve of a typical photovoltaic generator.

Referring to FIG. 1, the output control of the photovoltaic generator is performed by controlling the voltage to the left point (Left-Power Reserved Point, L-PRP) or right-power reserved point (R-PRP) of the maximum power point (MPP).

At this time, the solar generator has a maximum power value and output control value It has a reserve power equal to the difference in , and can contribute to the safe operation of the power system by participating in frequency adjustment using the reserve power.

The frequency adjustment system 10 according to an embodiment of the present invention is included in a power system together with a photovoltaic generator, and the frequency of the power system due to an event (for example, excessive supply of power due to a change in solar radiation) occurring in the photovoltaic generator can stabilize the frequency by controlling the output of the photovoltaic generator when it becomes unstable.

The frequency adjustment system 10 according to an embodiment of the present invention may include a first frequency adjustment module 100 , a second frequency adjustment module 200 and a generator output control module 300 .

The first frequency adjustment module 100 and the generator output control module 300 may perform first frequency adjustment (primary frequency adjustment).

Speaking in more detail about the first frequency adjustment (primary frequency adjustment), the first frequency adjustment module 100 measures the power system frequency based on frequency droop control and frequency change rate control. The first output command value to enter within this target frequency range It can be configured to calculate.

At this time, the target frequency range is the rated frequency from It may be a frequency corresponding to, for example, the rated frequency When is 60 [Hz], the target frequency range may be 59.8 [Hz] to 60.2 [Hz].

1st output command value After the calculation, the generator output control module 300 is the first output command value It may be configured to increase the output of the photovoltaic generator for a predetermined time and then reduce it to the original output by as much as possible.

Power grid frequency measurement by primary frequency adjustment, which is typically performed when an event occurs in a photovoltaic generator is recovered within the target frequency range, and the power system frequency measurement value When it recovers within this target frequency range, the automatic generation control (AGC) measures the power grid frequency. is the rated frequency can return to

2 is a block diagram of a first frequency adjustment module 100 according to an embodiment of the present invention.

Referring to FIG. 2 , the first frequency adjustment module 100 may include a frequency droop control output command value calculator 110, a frequency change rate control output command value calculator 120, and a first output command value calculator 130.

When an event occurs, the first frequency adjustment module 100 may be configured in a combination of frequency droop control and frequency change rate control.

For frequency droop control, power grid frequency measurements based on event occurrence It operates most effectively when it reaches this lowest frequency, and at this time, the frequency change rate control output command value becomes the smallest.

In the case of frequency regulation, the measured value of the power grid frequency as an event occurs. It operates most effectively at the moment when the frequency drops most rapidly (the moment when the fluctuation rate is the largest), and at this time, the frequency droop control output command value becomes gradually larger.

Therefore, the first frequency adjustment module 100 can complement each other's disadvantages by using both the frequency droop control and the frequency change rate control together.

The frequency droop control output command value calculation unit 110 is a frequency droop control gain value , the power grid frequency measurement and rated frequency Frequency droop control output reference value based on It can be configured to calculate.

More specifically, the frequency droop control output command value calculator 110 calculates the frequency droop control output command value through Equation 1 below. can be calculated.

[Formula 1]

The frequency change rate control output command value calculation unit 120 is a frequency change rate control gain value , the power grid frequency measurement and power grid frequency measurement recovery rate Frequency regulation control output command value based on It can be configured to calculate.

In more detail, the frequency change rate control output command value calculator 120 calculates the frequency change rate control output command value through [Equation 2] below. can be calculated.

[Equation 2]

The first output command value calculation unit 130 is an output control value , frequency droop control output command value and frequency change rate control output command value 1st output command value based on It can be configured to calculate.

More specifically, the first output command value calculator 130 calculates the first output command value through [Equation 3] below. can be calculated.

[Formula 3]

The first output command value by the first frequency adjustment module 100 When is calculated, the generator output control module 300 calculates the first output command value power system frequency measurement by varying the output of the solar generator by It can be made to enter within this target frequency range.

However, in some cases, power grid frequency measurements despite the first frequency adjustment (primary frequency adjustment) It may not fall within this target frequency range.

At this time, the frequency adjustment system 10 according to an embodiment of the present invention may perform second frequency adjustment (secondary frequency adjustment), which is additional frequency adjustment, through the second frequency adjustment module 200 and the generator output control module 300.

3 is a graph showing how the output of a photovoltaic generator is controlled according to time in a second frequency adjustment process through a second frequency adjustment module 200 and a generator output control module 300 according to an embodiment of the present invention, and FIG. 4 is a block diagram of the first frequency adjustment module 100 and the second frequency adjustment module 200 according to an embodiment of the present invention.

Referring to FIGS. 3 and 4 , the second frequency adjustment module 200 may include an entire power system required output calculation unit 210, an additional output command value calculation unit 220, and a second output command value calculation unit 230.

The second frequency adjustment module 200 and the generator output control module 300 may perform second frequency adjustment (secondary frequency adjustment).

Speaking in more detail about the second frequency adjustment (secondary frequency adjustment), the second frequency adjustment module 200 measures the power system frequency after a predetermined time has elapsed despite the first frequency adjustment. Phosphorus stabilization frequency If does not enter the target frequency range, the target power grid frequency recovery rate is specified, and the specified target power grid frequency recovery factor Power grid frequency measurements based on Second output command value to enter within this target frequency range It can be configured to calculate.

At this time, the second output command value is the first output command value Output command value added to It may be a value plus

Additional output command value Power grid frequency measurements when is small this rated frequency There is a disadvantage that the time to reach is long, and the additional output command value The higher the value, the faster the rated frequency can be reached, but after the second frequency adjustment, the output of the photovoltaic generator is again lowered and the frequency is highly likely to fall again.

Therefore, in the second frequency adjustment module 200, the target power system frequency recovery rate is specified, and the specified target power grid frequency recovery factor additional output reference value based on The second output command value that can minimize the above disadvantages by calculating can be obtained.

The power system total required output calculation unit 210 is a target power system frequency recovery rate is specified, and the specified target power grid frequency recovery factor , the constant of inertia of the power system as a whole and the angular velocity of the photovoltaic generator at rated frequency. Required output of the entire power system based on It can be configured to calculate.

In more detail, the entire power system required output calculation unit 210 calculates the total required power of the power system through [Equation 4] below. can be calculated.

[Formula 4]

The additional output command value calculation unit 220 is the entire power system required output , total installed capacity of power system and solar generator capacity additional output reference value based on It can be configured to calculate.

More specifically, the additional output command value calculator 220 calculates the additional output command value through [Equation 5] below. can be calculated.

[Formula 5]

The second output command value calculating unit 230 is the first output command value calculated through the first frequency adjustment module 100 and the additional output command value calculated through the additional output command value calculation unit 220 Second output command value based on It can be configured to calculate.

More specifically, the second output command value calculator 230 calculates the second output command value through [Equation 5] below. can be calculated.

[Formula 6]

The second output command value by the second frequency adjustment module 200 When is calculated, the generator output control module 300 calculates the second output command value The output of the photovoltaic generator as much as the preset time A measure of power system frequency by increasing it for It can be made to enter within this target frequency range.

and It will be apparent that may vary depending on the characteristics of the power system to which the present invention is applied.

In addition, considering the frequency re-down, the target frequency range is slightly higher than the minimum frequency at which the AGC operates, for example, when the minimum range of frequencies at which the AGC can operate is 59.8 [Hz], it may be desirable to set the target frequency range slightly higher than this.

5 is a graph showing the output of a solar generator to which the frequency adjustment system 10 according to an embodiment of the present invention is applied, and FIG. 6 is a graph showing the frequency of the solar generator to which the frequency adjustment system 10 according to an embodiment of the present invention is applied.

Referring to FIGS. 5 and 6, each graph shows a graph of when the output control (Reserved) of a general photovoltaic generator is performed, when only the first frequency adjustment is performed (Conventional), and when the frequency adjustment system 10 according to an embodiment of the present invention is applied (Proposed).

Each graph simulates the situation in which a synchronous generator with an output of 40 [MW] is dropped when a 60 [MVA] photovoltaic generator performs output control at 90% in a power system with a total installed capacity of synchronous generators of 500 [MVA] and a total load of 300 [MW].

In the case of the Conventional method, compared to the Reserved method, although the lowest point at which the frequency decreases and the stabilization frequency are improved, frequency recovery through the AGC cannot be achieved as the AGC operating range of 59.8 [Hz] is not reached.

However, in the case of the proposed method according to the present invention, when it is detected that the stabilization frequency does not reach the target frequency range, which is the operating range of the AGC, the frequency is increased through the second frequency adjustment so that the AGC operation range can be entered.

That is, the AGC can be operated by entering the frequency within the target frequency range through the second frequency adjustment module 200 .

Although the present invention has been described through examples above, the above examples are only for explaining the idea of the present invention and are not limited thereto. Those skilled in the art will understand that various modifications can be made to the above-described embodiments. The scope of the present invention is defined only through the interpretation of the appended claims.

10 frequency adjustment system
100 first frequency adjustment module
110 Frequency droop control output command value calculator
120 Frequency change rate control output command value calculation unit
130 first output command value calculator
200 second frequency adjustment module
210 Total power system required output calculation unit
220 Additional output command value calculation unit
230 second output command value calculator
300 Generator Output Control Module

Claims (10)

A first frequency adjustment module configured to perform first frequency adjustment based on frequency droop control and frequency change rate control to calculate a first output command value for a power system frequency measurement value to enter a target frequency range;
a second frequency adjustment module configured to designate a target power system frequency recovery rate and calculate a second output command value by performing second frequency adjustment based on the designated target power system frequency recovery rate; and
A generator output control module configured to increase the output of the photovoltaic generator according to the first output command value or the second output command value;
The second frequency adjustment module:
A power system-wide required output calculation unit configured to designate a target power system frequency recovery rate and calculate a required power system-wide output based on the specified target power system frequency recovery rate, the power system-wide inertia constant, and the angular velocity of the photovoltaic generator at a rated frequency;
an additional output command value calculation unit configured to calculate an additional output command value based on the required power of the entire power system, the capacity of the entire power system, and the capacity of the photovoltaic generator; and
and a second output command value calculation unit configured to calculate a second output command value based on the first output command value and the additional output command value.
According to claim 1,
The second frequency adjustment module:
In spite of the first frequency adjustment, when the stabilization frequency, which is the power system frequency measurement value after a predetermined time has elapsed, does not enter the target frequency range, designate a target power system frequency recovery rate, and calculate a second output command value for the power system frequency measurement value to enter the target frequency range by performing second frequency adjustment based on the designated target power system frequency recovery rate,
The generator output control module:
The frequency adjustment system configured to increase the output of the photovoltaic generator for a predetermined time according to the second output command value and then reduce the output to the original output.
According to claim 2,
The first frequency adjustment module:
a frequency droop control output command value calculation unit configured to calculate a frequency droop control output command value based on a frequency droop control gain value, a power system frequency measurement value, and a rated frequency;
a frequency change rate control output command value calculation unit configured to calculate a frequency change rate control output command value based on a frequency change rate control gain value, a power system frequency measurement value, and a power system frequency measurement value recovery rate; and
and a first output command value calculation unit configured to calculate a first output command value based on the output control value, the frequency droop control output command value, and the frequency change rate control output command value.
delete According to claim 3,
The frequency droop control output command value calculator:
Calculate the frequency droop control output command value through [Equation 1] below,
[Equation 1]

Is the frequency droop control output command value,
Is the frequency droop control gain value,
is the power system frequency measurement value,
is the rated frequency, the frequency regulation system.
According to claim 3,
The frequency change rate control output command value calculator:
Calculate the frequency change rate control output command value through [Equation 2] below,
[Equation 2]

Is the frequency change rate control output command value,
Is the frequency change rate control gain value,
is the power system frequency measurement value,
is the power system frequency measurement recovery factor, frequency regulation system.
According to claim 3,
The first output command value calculator:
Calculate the first output command value through [Equation 3] below,
[Formula 3]

Is the first output command value
is the output control value,
Is the frequency droop control output command value,
Is the frequency regulation control output command value, the frequency adjustment system.
According to claim 1,
The entire power system required output calculation unit:
Through [Equation 4] below, the required output of the entire power system is calculated,
[Formula 4]

is the required output of the entire power system,
is the power system overall inertia constant,
is the angular velocity of the photovoltaic generator at the rated frequency,
Is the target power system frequency recovery rate, the frequency regulation system.
According to claim 1,
The additional output command value calculator:
Calculate the additional output command value through [Equation 5] below,
[Formula 5]

is the additional output command value,
is the required output of the entire power system,
is the total installed capacity of the power system,
is the photovoltaic generator capacity, frequency regulation system.
According to claim 1,
The second output command value calculator:
Calculate the second output command value through [Equation 6] below,
[Formula 6]

Is the second output command value,
Is the first output command value,
Is the additional output command value, the frequency adjustment system.