JP7331587B2 - Negawatt trading support device, negawatt trading system and negawatt trading method - Google Patents

Description

The present invention relates to a negawatt trading support device, a negawatt trading system and a negawatt trading method, and more particularly to a negawatt trading supporting device, a negawatt trading system and a negawatt trading method for realizing a virtual power plant.

Conventional power grids generally take the form of supplying power generated by large-scale power plants such as thermal power plants and hydroelectric power plants to businesses and households that are consumers of electricity. Since electricity has the property that it cannot be stored, it is necessary to balance demand power and supply power in order to maintain the quality of electricity. In conventional power grids, supply and demand are balanced by adjusting the amount of power generated by large power plants in accordance with changes in the amount of power required by consumers.

In recent years, a power network using a virtual power plant (VPP) has attracted attention as an alternative power network to such a conventional power network. The virtual power plant is a decentralized system that uses advanced energy management technology that makes full use of IoT in order to utilize widely spread energy resources (distributed energy resources) such as solar power generation, storage batteries, electric vehicles, and negawatts (conserved electricity). remote and integrated control of energy resources, and realizes functions as if they were a single power plant.

In this way, technology for controlling power through negawatt trading, which is one of the distributed energy resources of virtual power plants, is expected to spread as elemental technology of virtual power plants.

On the other hand, among consumers, there are consumers (hereinafter also referred to as “received power adjustment consumers”) that have received power adjustment equipment that adjusts received power so that the received power is equal to or less than the contracted power threshold. Receiving power adjustment equipment uses regular power generation equipment such as storage battery systems and in-house power generation facilities and demand controllers, and when the load on the receiving power adjustment consumer increases, power is supplied from the regular power generation equipment to the load of the receiving power adjustment consumer. It supplies and adjusts the received power to the power below the contract power threshold. In a facility using a demand controller, when the load on the receiving power adjustment consumer increases, the demand controller selectively cuts off the load in the receiving power adjustment consumer to keep the received power below the contract power threshold. there is

For example, if the receiving power adjustment equipment is regular power generation equipment and the power adjustment consumer has a storage battery system as the regular power generation equipment, the purpose is to cut the peak of the received power. properly adjusted.

Patent Literature 1 proposes a negawatt transaction support device that enables negawatt transactions without modifying or replacing the existing received power adjustment equipment of such a received power adjustment consumer.

JP 2018-160949 A

FIG. 7 shows a negawatt transaction support device described in Patent Document 1. As shown in FIG. In FIG. 7, the negawatt transaction support device 60 can be used as an additional configuration in the storage battery system 1, which is the existing received power adjustment facility of the received power adjustment consumer. The storage battery system 1 is connected in parallel to a load 2 and can supply the load 2 with the storage battery output Pbat in addition to the received power PjA. The control device 10 determines a target output Pbatref of the storage battery system 1 based on the input received power PjA and the storage battery output Pbat of the storage battery system 1, and outputs the target output Pbatref to the power conversion device 12 to adjust the output of the storage battery 11. Thus, the storage battery output Pbat is controlled.

A negawatt transaction support device 60 of FIG. The negawatt trading support device 60 converts the received power PjA into a virtual received power PjB according to the received power reduction amount included in the demand response command that triggers the negawatt trading, and inputs the virtual received power PjB to the control device 10 to perform the negawatt trading. Realized. A demand response command (hereinafter also referred to as "DR command") is a signal that instructs the demand response, and the value specified by the demand response (hereinafter also referred to as "DR value") and the demand response such as the start time and end time of the demand response contains the instructions necessary to execute the

However, even if it is possible to adjust the amount of reduction in power demand in negawatt trading, if the amount of power required by consumers increases, the amount of power demand will increase accordingly, and the expected amount of power demand will be exceeded. may be lost. If the expected power demand is exceeded, there is a problem that the power demand cannot be adjusted reliably throughout the power network.

Focusing on the frequency, the conventional negawatt transaction support device has a function (so-called governor-free function) to adjust the self-end frequency (the frequency of the system, hereinafter also referred to as the power supply frequency), and a predetermined power supply when the frequency drops. There was no EPPS (Emergency Power Preset Switch) function for emergency power transmission.
When the balance of power supply and demand is maintained, the power supply frequency matches the reference frequency (eg, 50 Hz). However, if the power supply frequency drops significantly due to an accident or the like, it may lead to a power outage, so it is necessary to increase the supply (power generation amount, discharge amount) or decrease the demand. Additionally, when the power supply frequency rises significantly, it is necessary to either decrease the supply (power generation amount, discharge amount) or increase the demand.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems. To provide a negawatt trading support device, a negawatt trading system, and a negawatt trading method capable of realizing negawatt trading for surely executing power demand adjustment in the whole, when the power supply frequency drops. To provide a governor-free function for increasing the output immediately and reducing the output when the power supply frequency rises, and an EPPS function in an emergency.

A negawatt trading support device according to a representative embodiment of the present invention is configured such that when the load power of a load receiving power supply from the outside via a power receiving point fluctuates, the value of the received power at the power receiving point changes to a predetermined value. A control device that feeds back the value of the output of an auxiliary power source that supplies power to the load separately from the received power, using the value of the received power as an input so that the load following threshold, which is a threshold, is not exceeded. a DR command receiving unit for receiving a target reduction amount indicating that the reduction amount of the received power is set to a specified value as a demand response command in negawatt trading; and a DR command receiving unit for reducing the received power. a baseline calculation unit that calculates a baseline value that serves as a reference for the measurement, a received power target value calculation unit that calculates a received power target value by subtracting the target reduction amount from the baseline, and a power supply at a power receiving point A frequency deviation that is a difference between the frequency and the reference frequency is converted into a first frequency deviation correction value that is a power value, and a predetermined offset value is added to the first frequency deviation correction value to obtain a second frequency deviation. a frequency deviation correction unit that calculates a correction value; and a frequency deviation corrected received power target value calculation that calculates a frequency deviation corrected received power target value by subtracting the second frequency deviation corrected value from the received power target value. a bias value calculating unit for calculating a received power target bias value by subtracting the frequency deviation corrected received power target value from the load following threshold, and adding the received power target bias value to the received power value. and a virtual received power calculation unit for inputting the calculated virtual received power value to the control device instead of the value of the received power at the power receiving point. do.

A negawatt trading system according to a representative embodiment of the present invention is a negawatt trading system that transmits a demand response command to the negawatt trading support device, wherein the plurality of negawatt trading support devices that receive the demand response command means for managing the received power at the receiving point corresponding to each of the above; means for generating a demand response command to be transmitted to the corresponding negawatt trading support device based on the received power managed by the managing means; characterized by having

A negawatt transaction support method according to a representative embodiment of the present invention provides a method for supporting a negawatt transaction in which the value of the received power at a power receiving point changes to a predetermined Negawatt trading of a control device that feedback-controls the value of the output of an auxiliary power source that supplies power to the load separately from the received power, using the value of the received power as an input so as not to exceed the load following threshold, which is a threshold. , wherein the step of receiving a target reduction amount for setting the reduction amount of the received power to a specified value as a demand response command in negawatt trading, and reducing the received power a step of calculating a baseline value that serves as a reference for; a step of subtracting the target reduction amount from the baseline to calculate a received power target value; a step of converting the frequency deviation into a first frequency deviation correction value, which is a power value, and adding a predetermined offset value to the first frequency deviation correction value to calculate a second frequency deviation correction value; subtracting the second frequency deviation correction value from the received power target value to calculate a frequency deviation corrected received power target value; and subtracting the frequency deviation corrected received power target value from the load following threshold. calculating a target received power bias value; adding the target received power bias value to the value of the received power to calculate virtual received power; and inputting to the control device instead of the value of electric power.

It is a block diagram which incorporated the negawatt transaction support apparatus which concerns on one Embodiment in the existing receiving power adjustment equipment. 3 is a functional block of a frequency deviation correction circuit including a frequency deviation correction unit and a frequency deviation corrected received power target value calculation unit; FIG. 3 is a graph showing changes in target reduction achieved by the frequency deviation correction circuit of FIG. 2; FIG. It is a figure explaining an example of DR operation|movement of the receiving power adjustment installation incorporating the negawatt transaction support apparatus which concerns on one Embodiment. It is a figure for demonstrating the relationship between the target reduction amount in DR operation|movement, and a fluctuation|variation of a power supply frequency. It is a figure for demonstrating the conceptual structure of a virtual power plant. It is a figure for demonstrating the conventional negawatt transaction support apparatus.

1. Outline of Embodiment First, an outline of a representative embodiment of the invention disclosed in the present application will be described. In the following description, as an example, reference numerals on the drawings corresponding to constituent elements of the invention are described with parentheses.

[1] A negawatt trading support device (30) according to a representative embodiment of the present invention provides a power receiving point at a power receiving point when load power to which power is supplied from the outside via the power receiving point fluctuates. Feedback control is performed on the value of the output of an auxiliary power source that supplies power to the load separately from the received power, using the value of the received power as an input so that the power value does not exceed a load following threshold that is a predetermined threshold. A DR command receiving unit ( 31), a baseline calculation unit (32) that calculates a value of a baseline P0 that serves as a reference for reducing the received power, and a received power target value that subtracts the target reduction amount Pt from the baseline. A received power target value calculation unit (33) that calculates Pset, and converts a frequency deviation Δf that is the difference between the power supply frequency f at the power receiving point and the reference frequency into a first frequency deviation correction value Pco that is a power value, a frequency deviation correction unit (34) for calculating a second frequency deviation correction value Pcorr by adding a predetermined offset value A to the first frequency deviation correction value Pco; a frequency deviation corrected received power target value calculator (35) for subtracting a frequency deviation correction value Pcorr to calculate a frequency deviation corrected received power target value Psetc; A bias value calculation unit (37) for subtracting the target value Psetc to calculate a received power target bias value Pbias, and adding the received power target bias value Pbias to the received power value PjA to calculate virtual received power. and a virtual received power calculator (39) for inputting the calculated virtual received power value PjB to the control device instead of the received power value PjA at the power receiving point.

[2] In the negawatt transaction support device (30), a predetermined load selected in advance among the loads is cut off.

[3] In the negawatt transaction support device (30), the auxiliary power source (11) is a storage battery.

[4] A negawatt trading system that transmits a demand response command to the negawatt trading support device (30), wherein at a power receiving point corresponding to each of the plurality of negawatt trading support devices (30) that receive the demand response command characterized by comprising means for managing received power, and means for generating a demand response command to be transmitted to a corresponding negawatt transaction support device (30) based on the received power managed by said managing means. negawatt trading system.

[5] The power receiving point is configured so that the value of the power received at the power receiving point does not exceed a load following threshold, which is a predetermined threshold, when the load power of the load that receives power supply from the outside via the power receiving point fluctuates. A negawatt trading support method for adapting a control device for feedback-controlling the value of the output of an auxiliary power source that supplies power to the load separately from the received power to the negawatt trading, using the value of power as an input, the negawatt trading support method comprising: A step of receiving a target reduction amount Pt indicating that the amount of reduction in the received power is set to a specified value as a demand response command in a transaction, and a step of calculating a baseline P0 value that serves as a reference for reducing the received power. a step of subtracting the target reduction amount Pt from the baseline to calculate a received power target value Pset; converting into a first frequency deviation correction value Pco and adding a predetermined offset value A to the first frequency deviation correction value Pco to calculate a second frequency deviation correction value Pcorr; subtracting the second frequency deviation correction value Pcorr from Pset to calculate a frequency deviation corrected received power target value Psetc; and subtracting the frequency deviation corrected received power target value Psetc from the load following threshold value Pgref. calculating a received power target bias value Pbias; adding the received power target bias value Pbias to the received power value PjA to calculate virtual received power; and inputting to the control device instead of the value PjA of the received power at the power receiving point.

2. Specific Examples of Embodiments Specific examples of embodiments of the present invention will be described below with reference to the drawings. In the following description, constituent elements common to each embodiment are denoted by the same reference numerals, and repeated descriptions are omitted.

FIG. 1 is a configuration diagram in which a negawatt transaction support device according to one embodiment is incorporated into existing power receiving power adjustment equipment. In FIG. 1, the case where the receiving power adjustment equipment is the storage battery system 1 is mentioned as an example and demonstrated. The negawatt transaction support device 30 can be provided in the preceding stage of the control device 10 of the existing storage battery system 1, like the negawatt transaction support device 60 shown in FIG.

The storage battery system 1 includes a control device 10, a storage battery 11, and a power conversion device 12 for converting energy stored in the storage battery 11 into a storage battery output Pbat based on an output from the control device 10 and supplying the output to a load 2. ing. The storage battery system 1 is configured such that the storage battery output Pbat changes according to the received power. The control device 10 determines a storage battery system adjustment value Pbatref according to the input received power value and the storage battery output Pbat value, outputs the value to the power conversion device 12, and performs power conversion based on this storage battery system adjustment value Pbatref. The device 12 regulates the battery output Pbat.

The control device 10 includes a load power calculator 13 , a load following threshold value setter 14 , and a storage battery system adjustment value calculator 15 .

The load power calculator 13 calculates the value of the load by adding the storage battery output Pbat to the input received power. If the negawatt transaction support device 30 is not provided, the actual received power PjA received at the power receiving point is input to the control device 10 as the received power. 2 equal to the actual load power PL.

The load following threshold value setting unit 14 sets a threshold value for determining the output target of the storage battery system 1 . The output target value of the storage battery system 1 is calculated by the storage battery system adjustment value calculation unit 15 according to this threshold value. As the threshold value, a value according to the contract power is set. Although a value equal to the contract power may be set as the threshold, if a value lower than the contract power is set as the threshold, the storage battery system 1 can start operation with a margin. The number of thresholds that can be set is not limited to one, and a plurality of thresholds may be set so that control can be further set based on which threshold.

The storage battery system adjustment value calculation unit 15 sets a value for adjusting the output of the storage battery system 1 so that the load value calculated by the load power calculation unit 13 does not exceed the threshold set by the load following threshold setting unit 14. A storage battery system adjustment value Pbatref is calculated. The calculated storage battery system adjustment value Pbatref is output from the control device 10 to the power conversion device 12 .

The power conversion device 12 adjusts the output Pbat of the storage battery 11 according to the storage battery system adjustment value Pbatref received from the control device 10 .

In this way, the storage battery system 1 calculates the sum of the value of the output Pbat of the storage battery 11 and the value of the received power that changes with the output Pbat as the load value, and the calculated load value is used as the load following control device 10. A storage battery system adjustment value Pbatref, which is an adjustment value for the output Pbat of the storage battery 11, is calculated to control the output Pbat of the storage battery 11 so that the output Pbat of the storage battery 11 converges to a target value that is a threshold set as a threshold. That is, the output Pbat of the storage battery 11 is controlled so that the total value of the received power and the output Pbat of the storage battery 11 is set as the load following threshold as a target value, and the output Pbat of the storage battery 11 is controlled so as to converge to this value. This is equivalent to controlling the storage battery output Pbat so that the received power converges to a target value set as a load following threshold, and a so-called PI control feedback system in which the load following threshold is the target value and the received power is the feedback amount. It can be said that it constitutes The negawatt trading support device 30 converts a value specified by a DR command value (a value specified by a demand response) that triggers negawatt trading to a target value instead of the target value in the feedback system. is.

The negawatt transaction support device 30 includes a DR command receiving unit 31, a baseline calculating unit 32, a received power target value calculating unit 33, a frequency deviation correcting unit 34, a frequency deviation corrected received power target value calculating unit 35, It includes a load follow-up threshold value setting unit 36 , a bias value calculation unit 37 , a DR activation command unit 38 and a virtual received power calculation unit 39 .

The DR command receiving unit 31 can receive a DR command from a host device. In the present embodiment, the DR command receiving unit 31 uses, as the DR command in negawatt trading, a signal indicating the start/end time of the DR and a target reduction amount indicating that the reduction amount of the received power at the power receiving point is set to a specified value. Pt is included. In this embodiment, the host device includes a resource aggregator that configures a virtual power plant.

The baseline calculator 32 calculates the value of the baseline P0.
The baseline P0 is a value that serves as a reference when a consumer reduces received power in response to a DR command in negawatt trading. For example, the baseline P0 is the average value of the load power or received power at the consumer over the past several days at a predetermined time. For example, the average value of the load power specified every 30 minutes over the past five days can be used as the value of the baseline P0 at that hour. At the time of DR activation, it is preferable that the current load power PL and the baseline P0 of the consumer are close to each other.

The received power target value calculation unit 33 subtracts the target reduction amount Pt from the baseline P0 to calculate the received power target value Pset, and outputs the received power target value Pset after frequency deviation correction to the received power target value calculation unit 35 . This received power target value Pset is the target value of the received power when the received power at the power receiving point is reduced in accordance with the DR command.

The frequency deviation correction unit 34 receives the power supply frequency f at the power receiving point, calculates the second frequency deviation correction value Pcorr, and outputs it to the frequency deviation corrected received power target value calculation unit 35 as described in detail below. do.

The frequency deviation corrected received power target value calculation unit 35 subtracts the second frequency deviation correction value Pcorr from the received power target value Pset to calculate the frequency deviation corrected received power target value Psetc, and the bias value calculation unit 37 output to

The same value as the threshold set by the load following threshold setting unit 14 of the control device 10 is set as the threshold in the load following threshold setting unit 36 . For example, similarly to the load following threshold setting unit 14, a threshold Pgref (hereinafter also referred to as load following threshold Pgref) is set according to the contract demand. The load following threshold setting section 36 outputs the load following threshold Pgref to the bias value calculating section 37 .

The bias value calculator 37 subtracts the frequency deviation-corrected received power target value Psetc from the load following threshold Pgref to calculate a received power target bias value Pbias, and outputs the received power target bias value Pbias to the DR activation command unit 38 .

When the DR command receiving unit 31 receives the DR start time included in the received DR command as the DR command X, the DR command unit 38 sets the received power target bias value Pbias to synchronize with the time of the DR command X. to the virtual received power calculator 39 .

Upon receiving the received power target bias value Pbias, the virtual received power calculation unit 39 adds the received power target bias value Pbias to the actual received power PjA at the power receiving point, calculates the virtual received power PjB, and outputs the virtual received power PjB to the control device 10 . .

For example, when the DR is not activated (when the DR activation command signal X=0), the DR activation command unit 38 outputs “0”, so the virtual received power calculation unit 39 calculates the actual received power PjA 0 is added to the value of to calculate the virtual received power PjB. That is, when the command to activate DR is not given (when the DR activation command signal X=0), the value of the actual received power PjA is directly output as the received power PjB, and the control device 10 (load power calculation unit 13) , the actual received power PjA is used to calculate the load power PL.

On the other hand, when the DR is activated (when the DR activation command signal X=1), the DR activation command unit 38 outputs the "received power target bias value Pbias", so the virtual received power calculation unit 39 , "receiving power target bias value Pbias" is added to the value of the actual received power PjA to calculate the virtual power PjB. That is, when the DR is activated, the value obtained by raising (biasing) the actual received power PjA by the "target received power bias value Pbias" is output as the received power PjB. The power calculator 13) calculates the load power PL using the virtual received power PjB instead of the actual received power PjA.

When the negawatt transaction support device 30 is provided in the preceding stage of the storage battery system 1, the control device 10 can calculate the storage battery system adjustment value Pbatref based on the virtual received power PjB. It is possible to calculate the storage battery system adjustment value Pbatref for controlling the output Pbat of the storage battery system 1 so as to converge to the specified value Pset.

The received power target bias value Pbias calculated by the negawatt transaction support device 30 of the present embodiment is the value Pgref set as the threshold value by the load following threshold setting unit 14 in the control device 10 and the received power specified value Pset in the DR command. and the received power target value after frequency deviation correction Psetc obtained by correcting the frequency deviation. In other words, the received power target bias value Pbias calculated by the bias value calculator 37 can be said to be the difference between the original feedback target value and the newly set feedback target value. By adding this to the actual received power PjA in advance to calculate the virtual received power PjB and inputting it to the control device 10, instead of the threshold Pgref set by the load following threshold setting unit 14 in the control device 10, a new Using the frequency deviation corrected received power target value Psetc obtained by correcting the frequency deviation of the received power specified value Pset set to the feedback target value, the storage battery system adjustment value Pbatref is set so that the actual received power PjA at the power receiving point converges to this target value. will be calculated.

FIG. 2 is a diagram showing functional blocks of a frequency deviation correction circuit including the frequency deviation correction unit 34 and the frequency deviation corrected received power target value calculation unit 35. As shown in FIG.
The frequency deviation corrector 34 includes a frequency deviation calculator 341 , a converter 344 , an offset adjuster 345 , and an offset-adjusted frequency deviation calculator 346 .
The frequency deviation calculator 341 receives the power supply frequency f and the reference frequency (eg, 50 Hz) and calculates the frequency deviation Δf.
The converter 344 is a circuit that converts the frequency into a power value based on a predetermined gain (G), and converts the frequency deviation Δf into a first frequency deviation correction value Pco. The converter 344 has a limiter function with an upper limit of +0.5 Hz and a lower limit of -0.5 Hz, for example.
The offset adjuster 345 receives the power supply frequency f, outputs a predetermined offset value “+A” when f≦f1, and outputs a predetermined offset value “−A” when f≧f2. If f1<f<f2, "0" is output. The predetermined offset value A is set as |Pco|<<|A|. In this example, the predetermined offset values "+A" and "-A" have the same absolute value, but they may have different absolute values. Also, f1 is smaller than the lower limit of the converter 344, eg f1=49 Hz, and f2 is larger than the upper limit of the converter 344, eg f2=51 Hz.
It should be noted that the upper limit and lower limit of the limiter of the converter 344 as well as f1 and f2 can be set to arbitrary values.
The offset-adjusted frequency deviation calculator 346 adds the output from the offset adjuster 345 to the first frequency deviation correction value Pco, and outputs the second frequency deviation correction value Pcorr.
As described above, the frequency deviation corrected received power target value calculator 35 subtracts the second frequency deviation correction value Pcorr from the received power target value Pset to calculate the frequency deviation corrected received power target value Psetc.

A specific f will be described below with reference to FIGS. 2 and 3. FIG.
FIG. 3 is a graph showing changes in the target reduction amount achieved by the frequency deviation correction circuit of FIG. 2, where the horizontal axis indicates the power supply frequency and the vertical axis indicates the target reduction amount.

When f=50.1 Hz, Δf=0.1, which is inside the limiter of the converter 344, so the converter 344 converts the frequency deviation Δf into the first frequency deviation correction value Pco. Since f1 (=49)<f<f2 (=51), the offset adjustment section 345 outputs 0. The offset-adjusted frequency deviation calculator 346 outputs the first frequency deviation correction value Pco as the second frequency deviation correction value Pcorr.
The received power target value after frequency deviation correction Psetc becomes Psetc=Pset−Pcorr, and decreases by Pcorr, and the target reduction amount also decreases.
When f=49.9 Hz, Δf=−0.1, which is inside the limiter of the converter 344, so the converter 344 converts the frequency deviation Δf into the first frequency deviation correction value Pco. Since f1 (=49)<f<f2 (=51), the offset adjustment section 345 outputs 0. The offset-adjusted frequency deviation calculator 346 outputs the first frequency deviation correction value Pco as the second frequency deviation correction value Pcorr.
The received power target value after frequency deviation correction Psetc is Psetc=Pset−Pcorr, but since Pcorr is a negative value, the received power target value after frequency deviation correction Psetc increases by Pcorr, and the target reduction amount also increases. do.

As shown in FIG. 3, when 49.5<f<50.5, when the power supply frequency f increases from the reference frequency (for example, 50 Hz) (frequency deviation Δf>0), the second frequency deviation correction value Pcorr >0, the frequency deviation correction circuit decreases the target reduction amount. On the other hand, when the power supply frequency f decreases from the reference frequency (eg, 50 Hz) (frequency deviation Δf<0), the frequency deviation correction circuit increases the target reduction amount because the second frequency deviation correction value Pcorr<0.
Thus, by providing the frequency deviation correction circuit for correcting the frequency deviation, it is possible to convert the power supply frequency fluctuations into power fluctuations and control the target reduction amount.

If f1<f≦49.5 or 50.5≦f<f2, 0.5<|Δf|, which exceeds the limiter of the converter 344, the converter 344 outputs a constant value. Since f1 (=49)<f<f2 (=51), the offset adjustment section 345 outputs 0. The offset-adjusted frequency deviation calculator 346 outputs the first frequency deviation correction value Pco, which is a constant value, as the second frequency deviation correction value Pcorr. Since the second frequency deviation correction value Pcorr is also a constant value, the target reduction amount is also a constant value.
FIG. 3 shows that the target reduction amount becomes a constant value when f1<f≦49.5 or 50.5≦f<f2.

When f≦f1 (=49), the converter 344 outputs a constant value, and the offset adjuster 345 outputs a predetermined offset value A. The offset-adjusted frequency deviation calculator 346 adds a predetermined offset value A to the first frequency deviation correction value Pco, and outputs a second frequency deviation correction value Pcorr=Pco+A. Since |Pco|<<|A|, the target reduction is greatly increased.
FIG. 3 shows that the target reduction amount increases greatly when f≦f1.
In this way, when the power supply frequency f drops significantly due to an accident or the like, the power supply frequency f can be returned to the reference frequency by executing the EPPS function of greatly increasing the target reduction amount.

Additionally, when f≧f2 (=51), the converter 344 outputs a constant value, and the offset adjuster 345 outputs a predetermined offset value −A. The offset-adjusted frequency deviation calculator 346 subtracts a predetermined offset value A from the first frequency deviation correction value Pco and outputs a second frequency deviation correction value Pcorr=Pco−A. Since |Pco|<<|A|, the target reduction is greatly reduced.
FIG. 3 shows that the target reduction amount is greatly reduced when f≧f2.
In this way, when the power supply frequency f increases greatly due to an accident or the like, the power supply frequency f can be returned to the reference frequency by greatly decreasing the target reduction amount.

FIG. 4 is a diagram illustrating an example of DR operation in a power receiving power adjustment facility incorporating the negawatt transaction support device of one embodiment. In FIG. 4, (a) and (b) are shown along the same time axis, and the graph of (a) shows the fluctuation of the actual received power PjA received at the power receiving point of the consumer at the baseline P0 and the fluctuation of the load power PL of the day at the consumer, and the graph of (b) shows the fluctuation of the storage battery output Pbat. For the sake of explanation, FIG. 4A shows the received power target value Pset that is substantially equal to the actual received power PjA from time T1 to time T8.
First, assume that the power supply frequency f matches the reference frequency (ie, Pcorr=0).

In FIG. 4, DR command receiving unit 31 receives a DR command to start DR at time T1 and a DR command to end DR at time T8. showing. In FIG. 4, before time T1, the load power PL is covered by the actual received power PjA, and the actual received power does not exceed the contract power threshold Pgref. Therefore, the storage battery output Pbat is "0".

When the DR command receiving unit 31 receives the target reduction amount Pt, the received power target value calculation unit 33 subtracts the target reduction amount Pt at time T1 from the baseline P0 at time T1, thereby obtaining the target received power at time T1. The value Pset is calculated and output to the received power target value calculation unit 35 after frequency deviation correction.

The frequency deviation corrected received power target value calculation unit 35 subtracts the second frequency deviation correction value Pcorr (0 in this example) from the calculated received power target value Pset at time T1 to calculate the frequency deviation corrected received power target value. Calculate the value Psetc.

The bias value calculator 37 subtracts the frequency deviation-corrected received power target value Psetc from the load following threshold value Pgref to calculate a received power target bias value Pbias.
The virtual received power calculation unit 39 adds the received power target bias value Pbias to the actual received power PjA immediately before T1 to obtain the virtual received power PjB.

When control device 10 receives virtual received power PjB, load power calculation unit 13 calculates virtual load PLB by adding storage battery output Pbat at the point immediately before T1 to virtual received power PjB, and storage battery system adjustment value calculation unit 15 output to

The storage battery system adjustment value calculation unit 15 subtracts the load following threshold Pgref from the received virtual load PLB, calculates the storage battery system adjustment value Pbatref according to the subtracted value, and outputs the calculated storage battery system adjustment value Pbatref to the power converter 12 . The power conversion device 12 adjusts the output Pbat of the storage battery 11 based on the storage battery system adjustment value Pbatref. The received power adjustment facility incorporating the negawatt transaction support device of the present embodiment repeats the DR operation similar to the DR operation at time T1 described above according to the value corresponding to that time, and adjusts the output Pbat of the storage battery 11. can be done.

As shown in FIG. 4, at each point in time, the output Pbat (B1, B2, B3) of the storage battery 11 adjusted by the storage battery system adjustment value Pbatref is the load power PL and the received power target value Pset (=received power after frequency deviation correction). It is equal to the differences B1, B2, and B3 from the power target value Psetc). In this way, the output Pbat of the storage battery 11 is adjusted to a value that compensates for the difference between the load power PL and the received power target value Pset (=received power target value after frequency deviation correction Psetc). , converges to a value equal to the target value Pset.

In the case shown in FIG. 4, the target reduction amount Pt is constant, and the baseline P0 fluctuates at predetermined time intervals ΔT. It fluctuates at a predetermined time interval ΔT. The storage battery system adjustment value Pbatref is determined so that the output Pbat of the storage battery 11 becomes a value that compensates for the difference between the load power PL and the received power target value Pset (=received power target value after frequency deviation correction Psetc). Therefore, the values of the differences B1, B2, and B3 between the load power PL and the received power target value Pset (=received power target value after frequency deviation correction Psetc) at each time are the output Pbat (B1, B2, B3) of the storage battery 11 and be equal.

Next, the case where the power supply frequency f deviates from the reference frequency within the range of 49.5<f<50.5 will be described.
FIG. 5 is a diagram for explaining the relationship between the target reduction amount and the power frequency fluctuation in the DR operation. 5(a), 5(b) and 5(c), the horizontal axis represents time, the vertical axis represents frequency in FIG. 5(a), and the vertical axis represents power in FIGS. 5(b) and 5(c). ing.
DR command receiving unit 31 receives a DR command to start DR at time T1 and a DR command to end DR at time T8.
As shown in FIG. 5(a), the power supply frequency f fluctuates with respect to the reference frequency (eg, 50 Hz).

FIG. 5(b) shows the baseline and received power when frequency deviation correction is not performed.
The target reduction amount is the difference between the baseline and the received power.
FIG. 5(c) shows the baseline and received power when the frequency deviation is corrected. Also in FIG. 5(c), the received power when the frequency deviation correction is not performed is indicated by the one-dot chain line.
In the period P1, as shown in FIG. 5A, the power supply frequency f is higher than the reference frequency, and as shown in FIG. )taller than. Therefore, compared with the case of FIG.5(b), the target reduction amount is decreasing.
In the period P2, as shown in FIG. 5A, the power supply frequency f is lower than the reference frequency, and as shown in FIG. ) lower. Therefore, compared with the case of FIG.5(b), the target reduction amount is increasing.

In this way, when the power supply frequency f rises above the reference frequency, the target reduction amount is decreased (=the received power is increased and the power demand is increased). Adjust supply and demand by increasing the amount of reduction (=reducing received power, reducing power demand).
As described above, by installing the frequency adjustment function (governor-free function) in the negawatt trading device 100, the charge/discharge power can be controlled by regarding the fluctuation of the power supply frequency f as the fluctuation of the received power.

When the power supply frequency f deviates from the reference frequency in the range of f≦f1, the EPPS function is used to greatly increase the target reduction amount as described above instead of increasing the target reduction amount depending on the frequency. By executing, the power supply frequency f can be returned to the reference frequency.
Additionally, when the power supply frequency f deviates from the reference frequency within the range of f≧f2, the power supply frequency f can be returned to the reference frequency by greatly decreasing the target reduction amount.

In addition to increasing the target reduction amount described above, the lowered power supply frequency f can be returned to the reference frequency by disconnecting the load from the grid using the contact function of the negawatt transaction support device.
For example, for a load such as an air conditioner, even if the power supply is interrupted for a certain period of time in an emergency, the impact on the consumer is considered to be small. Therefore, in the contract with the consumer, if the load that can be disconnected in an emergency is selected in advance and the power supply frequency f cannot be returned to the reference frequency in an emergency by simply increasing the target reduction amount described above. , interrupts the power supply to the selected load.
In this way, in addition to increasing the target reduction amount (increasing the power supply), interrupting the power supply to the load (reducing the demand) makes it possible to reliably return the power supply frequency f to the reference frequency. can.

Additionally, when the power supply frequency f increases significantly, in addition to decreasing the target reduction amount (decreasing the power supply), by increasing the power supply to the load (increasing the demand), , the power supply frequency f can be reliably returned to the reference frequency.

FIG. 6 is a diagram for explaining the conceptual configuration of the virtual power plant. In FIG. 6, the aggregation coordinator AC is centered, and power plants PP1, PP2, PP3, and PP4 and resource aggregators RA1, RA2, RA3, RA4, and RA5 are included below it, and resource aggregators RA1, RA2, RA3, and RA4 are included. , RA5 include consumers C1 to C19 below them.

Here, power plants refer to general power transmission and distribution companies and retail power companies. A resource aggregator is a business operator that directly concludes a virtual power plant service contract with a consumer and controls power resources. An aggregation coordinator is a business operator that bundles power controlled by a resource aggregator and conducts direct power transactions with general power transmission/distribution companies and retail power companies.

In the virtual power plant, information processing devices such as computers that process information in these components are communicably connected to each other according to the configuration shown in FIG. 6, and control power resources. In the following explanation, the operation of the information processing device in the constituent elements that make up the virtual power plant is explained as the operation of each constituent element.

Consumers C1 to C19 include received power adjustment consumers having received power adjustment equipment that adjusts received power so that the received power is equal to or less than the contracted power threshold. Receiving power adjustment Consumers operate their own receiving power adjustment equipment in response to a request to suppress power demand to reduce the received power, but instead receive compensation for suppressing power demand, so-called negawatt transactions. can be done. Negawatt trading can be realized by using the negawatt trading support device 30 according to one embodiment described above. Negawatt transactions in consumers C1-C19 are performed with their upper resource aggregators RA1-RA5.

The resource aggregators RA1 to RA5 have management means for managing the received power of the respective lower consumers C1 to C19, and request negawatt transactions to the negawatt transaction support devices 30 possessed by the consumers C1 to C19. It has transmission means for transmitting a DR command for Furthermore, the resource aggregators RA1-RA5 can have means for generating DR commands based on the received power of each of the consumers C1-C19 managed by the management means. By generating the DR command based on the managed received power of each of the consumers C1 to C19, it is possible to generate the DR command considering the received power of each consumer.

Aggregation coordinator AC controls the DR value between consumers C1-C19 and resource aggregators RA1-RA5 that conduct negawatt transactions and between power plants PP1-PP4 to balance supply and demand of electric power in the entire virtual power plant. to trade negawatts.

When the resource aggregators RA1 to RA5 are requested to suppress a certain amount of power demand as a DR, the resource aggregators RA1 to RA5 send the DR to the consumers C1 to C19. Send orders. When performing DR, it is conceivable that the DR designates the amount of reduction in the received power and the DR directly designates the received power. According to the DR that directly specifies the received power, it is possible to avoid a situation in which the amount of power demand suppression does not meet the required amount when the power load is significantly different from normal.

The present invention is not limited to the embodiments described above, and various modifications are possible.
For example, in the embodiment described above, the DR command receiving unit received the target reduction amount Pt as the DR command, but it is also possible to receive the received power target value Pset.
Further, in the above-described embodiment, the frequency deviation correction circuit including the frequency deviation correction unit 34 and the frequency deviation corrected received power target value calculation unit 35 is provided in the negawatt transaction support device provided before the control device 10 of the storage battery system 1. , but a similar frequency deviation correction unit can also be added in the negawatt transaction support device provided before the control device of the generator system.

DESCRIPTION OF SYMBOLS 1... Storage battery system 2... Load 10... Control device 11... Storage battery 12... Power converter 13... Load power calculation part 14... Load following threshold value setting part 15... Storage battery system adjustment value calculation part 30... Negawatt transaction support device 31 DR command receiver 32 Baseline calculator 33 Received power target value calculator 34 Frequency deviation corrector 341 Frequency deviation calculator 344 Converter 345 Offset Adjusting unit 346... Offset-adjusted frequency deviation calculating unit 35... Received power target value calculating unit after frequency deviation correction 36... Load following threshold setting unit 37... Bias value calculating unit 38... DR activation commanding unit 39... Virtual received power calculation unit 60... Negawatt transaction support device.

Claims (7)

The value of the received power is adjusted so that the value of the received power at the power receiving point does not exceed a load following threshold, which is a predetermined threshold, when the load power of the load that receives power supplied from the outside via the power receiving point fluctuates. as an input, a negawatt transaction support device provided in the front stage of a control device that feedback-controls the value of the output of an auxiliary power source that supplies power to the load separately from the received power,
A DR command receiving unit that receives a target reduction amount for setting the reduction amount of the received power to a specified value as a demand response command in negawatt trading;
a baseline calculation unit that calculates a baseline value that serves as a reference for reducing the received power;
a received power target value calculation unit that calculates a received power target value by subtracting the target reduction amount from the baseline;
A frequency deviation that is the difference between the power supply frequency f and the reference frequency at the power receiving point is converted into a first frequency deviation correction value that is a power value, and a predetermined offset value is added to the first frequency deviation correction value. a frequency deviation correction unit that calculates a second frequency deviation correction value;
a frequency deviation corrected received power target value calculation unit that calculates a frequency deviation corrected received power target value by subtracting the second frequency deviation correction value from the received power target value;
a bias value calculation unit that calculates a received power target bias value by subtracting the received power target value after frequency deviation correction from the load following threshold;
adding the received power target bias value to the received power value to calculate virtual received power, and inputting the calculated virtual received power value to the control device in place of the received power value at the power receiving point; a virtual received power calculation unit;
with
A negawatt transaction support device, wherein when f≦f1 and f2≦f, the predetermined offset value is a constant value, and f1 and f2 are predetermined frequencies where f1<f2. characterized by disconnecting a predetermined load selected in advance from the load,
The negawatt transaction support device according to claim 1. The auxiliary power source is a storage battery,
The negawatt transaction support device according to claim 1 or 2. f1 is smaller than the lower limit frequency when converting to the first frequency deviation correction value,
The negawatt transaction support device according to any one of claims 1 to 3. A negawatt trading system that transmits a demand response command to the negawatt trading support device according to any one of claims 1 to 3,
means for managing received power at a power receiving point corresponding to each of the plurality of negawatt transaction support devices that receive the demand response command;
means for generating a demand response command to be transmitted to a corresponding negawatt transaction support device based on the received power managed by the managing means;
A negawatt trading system characterized by having: The value of the received power is adjusted so that the value of the received power at the power receiving point does not exceed a load following threshold, which is a predetermined threshold, when the load power of the load that receives power supplied from the outside via the power receiving point fluctuates. as an input, a negawatt trading support method for adapting a control device that feedback-controls the value of the output of an auxiliary power source that supplies power to the load separately from the received power to negawatt trading,
a step of receiving a target reduction amount for setting the reduction amount of the received power to a specified value as a demand response command in negawatt trading;
calculating a baseline value that serves as a reference for reducing the received power;
calculating a target received power value by subtracting the target reduction amount from the baseline;
A frequency deviation that is the difference between the power supply frequency f and the reference frequency at the power receiving point is converted into a first frequency deviation correction value that is a power value, and a predetermined offset value is added to the first frequency deviation correction value. calculating a second frequency deviation correction value;
a step of subtracting the second frequency deviation correction value from the received power target value to calculate a frequency deviation corrected received power target value;
calculating a received power target bias value by subtracting the received power target value after frequency deviation correction from the load following threshold;
adding the received power target bias value to the received power value to calculate virtual received power, and inputting the calculated virtual received power value to the control device in place of the received power value at the power receiving point; a step;
including
A negawatt trading support method, wherein, when f≦f1 and f2≦f, the predetermined offset value is a constant value, and f1 and f2 are predetermined frequencies where f1<f2. f1 is smaller than the lower limit frequency when converting to the first frequency deviation correction value,
The negawatt transaction support method according to claim 6.

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