JP7108524B2 - Charge/discharge control device and charge/discharge control method - Google Patents

Description

The present invention relates to a charge/discharge control device and a charge/discharge control method.

After 2019, a large amount of photovoltaic (PV) devices for residential use will be generated for which the purchase period of the Feed-in Tariff (FIT) system will end. At that time, in a household that uses both a power storage device and a solar power generation device, the surplus power of the solar power generation device (power generated by the solar power generation device minus the consumed power) during the daytime (daytime) is charged into the power storage device and discharged (consumed) during night hours (hereinafter referred to as surplus charge mode).

In addition, households using both a photovoltaic power generation device and a power storage device can obtain an incentive by participating in demand response (DR). At that time, although it depends on the charge system, in order to obtain an incentive for participating in the demand response, it is necessary to have a certain amount of electric power remaining in the power storage device that can be discharged.

JP-A-60-256824 Patent No. 5877346

However, in the surplus charge mode, the amount of charge to the power storage device during the daytime varies greatly depending on the weather during the daytime. In particular, when it is cloudy or rainy, it is difficult to participate in demand response because it is almost impossible to expect the solar power generation system to generate electricity during the daytime, and it is not possible to expect the surplus power of the solar power generation system to charge the storage device. there was a case.

Therefore, the present invention has been made in view of the above problems, and a charge/discharge control device and a charge/discharge control method that can appropriately control the amount of charge in a power storage device so as to enable participation in demand response. intended to provide

A first feature of the present disclosure is to charge a power storage device with power supplied by a power system during night hours, charge the power storage device with surplus power of a power generation device during daytime hours, and respond to requests from the power system. A charge/discharge control device capable of controlling the power flow rate and the reverse power flow rate between the electric power system according to a calculating unit for calculating the charging amount in the nighttime period based on the remaining amount, and a calculating unit configured to charge the power storage device with the electric power corresponding to the calculated charging amount in the nighttime period in the nighttime period. The gist is to have a control unit for controlling.

A second feature of the present disclosure is to charge a power storage device with power supplied by a power system during night hours, charge the power storage device with surplus power of a power generation device during daytime hours, and respond to requests from the power system. A charge/discharge control device capable of controlling a power flow rate and a reverse power flow rate to and from the electric power system according to the power generation prediction information of the power generation device, past power consumption information in the daytime period, and the power storage a calculation unit for calculating the charge amount of the surplus power for the power storage device to be fully charged at a predetermined time based on the remaining amount of the device; The gist of the present invention is to have a control unit that controls the power storage device to be charged with the surplus power corresponding to the charging amount of power.

A third feature of the present disclosure includes a step A of controlling the flow rate and the reverse flow rate with the power system in response to a request from the power system, and storing the power supplied by the power system during the night time period. Step B of charging the device; Step C of charging the power storage device with surplus power of the power generation device during the daytime period; weather forecast information for the next day, past power consumption information during the daytime time period, and the remaining amount of the power storage device; and a step D of calculating the charge amount in the night time period based on the amount of charge in the night time period, and in the step C, in the night time period, the charge amount in the night time period calculated in step D is calculated as the charge amount in the night time period. The gist of the present invention is to control a power storage device to be charged with the electric power.

According to the embodiments of the present invention, it is possible to provide a charge/discharge control device and a charge/discharge control method capable of appropriately controlling the amount of charge in a power storage device so as to enable participation in demand response.

FIG. 1 is a diagram illustrating an example of the overall configuration of a control system according to one embodiment. FIG. 2 is a diagram showing an example of a configuration of a charge/discharge control device according to one embodiment. FIG. 3 is a flow chart showing an example of the operation of the charge/discharge control device according to one embodiment. FIG. 4 is a diagram illustrating an example of the configuration of a control server according to one embodiment; FIG. 5 is a flowchart showing an example of the operation of the charge/discharge control device according to one embodiment.

A control system according to an embodiment of the present invention will be described below with reference to the drawings. In addition, in the following description of the drawings, the same or similar reference numerals are given to the same or similar parts.

(First embodiment)
A first embodiment of the present invention will be described below with reference to FIGS. 1 to 3. FIG. FIG. 1 is a diagram showing an example of the configuration of a control system 1 according to this embodiment. As shown in FIG. 1, the control system 1 has multiple facilities 100 and a control server 200 . Each facility 100 and control server 200 are connected to a communication network 20 . The communication network 20 may include the Internet, or may include a dedicated line such as a VPN (Virtual Private Network).

In FIG. 1, facilities 100A to 100C are illustrated as the plurality of facilities 100. As shown in FIG. One facility 100 corresponds to one consumer. Each facility 100 is connected to the power grid 10 .

Power flow from the power system 10 to the facility 100 is referred to as "tidal flow" and power flow from the facility 100 to the power grid 10 is referred to as "reverse power flow." The electric power system 10 may be a power transmission network outside the consumer in the case of power interchange between consumers in an area separated from the electric power company.

Facility 100 has power storage device 110 , power generation device 120 , EMS (Energy Management System) 130 , and load 140 .

In this embodiment, the power generation device 120 is a solar power generation device that generates power using sunlight.

The power storage device 110 is a device that charges and discharges under the control of the EMS 130 . For example, the power storage device 110 is a lithium ion power storage device, a lead power storage device, a nickel/hydrogen power storage device, or the like.

Note that the power discharged by the power storage device 110 may be supplied to load devices in the facility 100 or may be supplied to the power system 10 . Further, in this embodiment, the power generated by the power generation device 120 may be sold, and the load devices in the facility 100 may be operated in a “push-up mode” in which the discharge of the power storage device 110 is used.

The power storage device 110 can charge, for example, power supplied by the power system 10 or surplus power of a power generation device.

EMS130 is an apparatus which manages the electric power of the facility 100 (consumer). Specifically, the EMS 130 creates a control plan for controlling the charge/discharge of the power storage device 110 of the facility 100 according to the power demand of the facility 100, and sends the charge/discharge request to the control server 200 according to the created control plan. Send to EMS 130 also controls power storage device 110 in accordance with a charge/discharge instruction, which will be described later.

In FIG. 1 , the power output section of power generation device 120 is connected to the power line of power storage device 110 within facility 100 , and load 140 is connected to the power line of power storage device 110 and EMS 130 within facility 100 . Note that the load 140 does not necessarily have to be connected to the EMS 130 .

The control server 200 is a device that comprehensively controls charging and discharging of the power storage device 110 in the facility 100 . The control server 200 controls charging and discharging of a plurality of power storage devices 110 belonging to different consumers. For example, the control server 200 is managed by an electric power company such as a power generation company, a power transmission/distribution company, or a retailer.

Specifically, based on the charge/discharge request received from the EMS 130, the control server 200 stores the requested charge/discharge amount, which is the charge amount or discharge amount corresponding to the charge/discharge request, in at least one of the plurality of power storage devices 110. assign.

Further, the control server 200 transmits a charge/discharge instruction for controlling the power storage device 110 to which the requested charge/discharge amount is allocated, to the EMS 130 corresponding to the power storage device 110 .

Here, the control server 200 may activate a demand response to transmit a tidal flow rate control request (lowering DR) requesting control of the tidal flow rate. (Raise DR) may be transmitted. The control degree of the tidal flow rate or reverse tidal flow rate may be represented by an absolute value (for example, XX kW) or may be represented by a relative value (for example, XX%).

In this embodiment, it is assumed that the electricity rate in the nighttime period is lower than the electricity rate in the daytime period (for example, 7:00 to 23:00). Further, in the present embodiment, it is assumed that the electric power selling rate by the power generator 120 is lower than the electric power rate during the daytime hours. In the present embodiment, the EMS 130 charges the power storage device 110 with power supplied by the power system 10 during the nighttime hours, and charges the power storage device 110 with surplus power of the power generation device 120 during the daytime hours. Further, in the present embodiment, the power storage device 110 is not discharged while the surplus power of the power generation device 120 is being charged.

Further, in the present embodiment, the power storage device 110 does not discharge during the nighttime hours. Therefore, it is assumed that the remaining amount of power storage device 110 (power that can be discharged to power storage device 110) at the start of charging in the night time zone cannot be reduced.

Furthermore, in the present embodiment, since the power consumption during the daytime varies depending on the day, the remaining amount of the power storage device 110 at the start of charging the power storage device 110 with the power supplied by the power system 10 during the nighttime is always It is not necessarily constant.

In addition, the EMS 130 changes the power flow rate and the reverse power flow rate with the power system 10 (control server 200) in response to a request (power flow control request or reverse power flow control request) from the power system 10 (control server 200). can be controlled.

As shown in FIG. 2, the EMS 130 has a communication section 131, a database 132, and a control section .

The communication unit 131 is configured by a communication module, and communicates with an external communication device such as the control server 200 via the communication network 20 .

The database 132 is configured by a storage medium such as memory and/or HDD, and stores information and data used for control and processing in the calculator 133 and controller 134 .

The control unit 134 is composed of an arithmetic device such as a CPU or MPU, and has a calculation unit 133 . Control unit 134 is connected to power storage device 110 and power generation device 120 using communication unit 131 as an interface, and controls power storage device 110 and power generation device 120 . The control unit 134 is also connected to the control server 200 using the communication unit 131 as an interface.

Further, when the control unit 134 receives the above-described power flow control request and determines to respond to the power flow control request, the control unit 134 performs the following control.

When the power generated by the power generation device 120 is greater than the power consumption, the control unit 134 controls to reduce the amount of surplus power of the power generation device 120 charged to the power storage device 110, thereby meeting the power flow rate control request. answer.

On the other hand, when the power generated by the power generation device 120 is less than the power consumption, there is no surplus power of the power generation device 120. It is purchased from the power system 10. Therefore, the control unit 134 responds to the power flow rate control request by controlling the power storage device 110 to discharge.

Here, communication can be performed between the control server 200 and the EMS 130 using, for example, a protocol conforming to Open ADR (Automated Demand Response) or a unique dedicated protocol.

Further, communication can be performed between the EMS 130 and the power storage device 110 or the power generation device 120 using, for example, a protocol conforming to ECHONET Lite.

Note that there are cases where communication cannot be performed between control server 200 and power storage device 110 or power generation device 120, but there are cases where communication can be performed using a protocol conforming to Open ADR, for example.

Under the premise of the present embodiment described above, when the surplus power of the power generation device 120 is large, the surplus power of the power generation device 120 must be sold by fully charging the power storage device 110 .

Further, under the premise of the present embodiment described above, when the surplus power of the power generation device 120 is small, there is little room for responding to the power flow rate control request (lowering DR), or the power discharged from the power storage device 110 is insufficient. There is a possibility that

Calculation unit 133 calculates the amount of charging power storage device 110 with the power supplied by power system 10 in the nighttime period (that is, the charging amount in the nighttime period).

Specifically, calculation unit 133 calculates the amount of charge during the nighttime hours described above based on the weather forecast information for the next day, the past power consumption information during the daytime hours, and the remaining amount of power storage device 110 .

For example, the calculation unit 133 may use prediction information related to the next day's temperature (maximum temperature and minimum temperature), amount of solar radiation, atmospheric pressure (maximum atmospheric pressure and variation), etc., as the weather forecast information for the next day.

Further, the calculation unit 133 may use past power consumption information in a daytime period with a predetermined time granularity such as 12 hours or 24 hours, for example. Further, the calculation unit 133 may use past power consumption information in a daytime period with a time span of 1 day, 7 days, or 30 days, for example.

Further, calculation unit 133 uses the remaining amount of power storage device 110 at the start of charging of power storage device 110 with the power supplied by power system 10 in the nighttime period as the remaining amount of power storage device 110 .

For example, the calculation unit 133 uses the following (Equation 1) to (Equation 8) to calculate the amount of charging the power storage device 110 with the power supplied by the power system 10 in the nighttime period (that is, the charging amount in the nighttime power ) may be calculated.

Here, suppose the parameters α, β, γ, δ are estimated by logistic regression. Here, since the number of parameters varies depending on the number of explanatory variables to be given, let w be a parameter matrix in which the parameters α, β, γ, and δ have variable lengths. Then, data sets are prepared for cases where the surplus power of the power generation device 120 on the next day is large and small, and the parameter matrix w that maximizes the likelihood function L is calculated.

For example, the explanatory variable matrix x contains forecast information related to the amount of solar radiation, forecast information related to the maximum temperature, forecast information related to the minimum temperature, forecast information related to the maximum pressure, the remaining amount of the power storage device 110, and the power consumption from the previous day to the 7th day. When the information is entered, k=12.

Further, the calculation unit 133 may calculate the charge amount in the nighttime period based on the power consumption prediction information for the next day. According to such a feature, it is possible to more appropriately calculate the charge amount in the nighttime period by using the prediction information of the next day's power consumption.

The calculation unit 133 may acquire some or all of the various data from the database 132 or from an external server or the like via the communication unit 131 . Here, the various types of data include weather forecast information for the next day, past power consumption information during the daytime, the remaining amount of power storage device 110, forecast information for power consumption for the next day, and the like.

Further, the calculation unit 133 may calculate the various data described above based on information acquired from the database 132, an external server, or the like.

As a result, control unit 134 controls power storage device 110 to be charged with electric power supplied by power system 10 in the nighttime period by the charge amount in the nighttime period calculated by calculation unit 133 .

An example of the charge/discharge control method according to the present embodiment will be described below with reference to FIG.

In step S<b>101 , the EMS 130 acquires various data such as weather forecast information for the next day, past power consumption information during daytime hours, the remaining amount of the power storage device 110 , and forecast information for the next day's power consumption.

In step S<b>102 , the EMS 130 calculates the amount of charge in nighttime power based on the acquired various data.

In step S<b>103 , EMS 130 transmits a charge instruction including the calculated charge amount to power storage device 110 .

In step S<b>104 , the power storage device 110 starts charging the power supplied by the power system 10 in the nighttime period by the charging amount included in the charging instruction.

In step S<b>105 , EMS 130 determines whether or not it is necessary to periodically transmit a charging instruction to power storage device 110 . If Yes, the operation proceeds to step S106, and if No, the operation ends.

When EMS 130 determines in step S106 that the predetermined period has passed, in step S107 it determines whether power storage device 110 is storing power. If Yes, the operation proceeds to step S108, and if No, the operation ends. In step S<b>108 , EMS 130 transmits a charging instruction to power storage device 110 .

As a result, EMS 130 can periodically transmit the same charging instruction to power storage device 110 while power storage device 110 is being charged, as well as once before power storage device 110 starts charging.

According to this embodiment, since the power generation device 120 is hardly expected to generate power during the daytime hours, it is not expected that the power storage device 110 will be charged with the surplus power of the power generation device 120, and it is expected that the surplus power of the power generation device 120 will be small. Even in such a case, it is possible to prevent the remaining amount of power storage device 110 from becoming too low when charging in the nighttime period is completed by appropriately controlling the amount of charge in the nighttime period.

As a result, it is possible to secure a room for responding to the tidal flow control request (lowering DR), and to participate in the demand response (that is, to respond to the tidal flow control request and the reverse tidal flow control request). can be done.

Further, according to this embodiment, when the charging of the power storage device 110 with the surplus power of the power generation device 120 during the daytime is started, it is possible to avoid the situation where the power storage device 110 has a large residual amount remaining. can be done.

As a result, it is not possible to secure the capacity of the power storage device 110 for charging the surplus power of the power generation device 120 during the daytime, and the power storage device 110 is quickly fully charged, and the power generation device 120 can be charged at a low price. It is possible to avoid the problem of having to sell the surplus power of

(Second embodiment)
The second embodiment of the present invention will be described below with reference to FIG. 4, focusing on differences from the first and second embodiments described above.

As shown in FIG. 4 , the control server 200 according to this embodiment has a communication section 201 , a database 202 and a control section 204 .

The communication unit 201 is configured by a communication module, and communicates with the EMS 130 in each facility 100 and external communication devices via the communication network 20 .

The database 202 is configured by a storage medium such as memory and/or HDD, and stores information and data used for processing in the calculation unit 203 .

The control unit 204 is composed of an arithmetic device such as a CPU or MPU, and has a calculation unit 203 . Calculation unit 203 calculates the amount of power supplied by power system 10 in the night time period to charge power storage device 110 (that is, the amount of charge in nighttime power) in the same manner as calculation unit 133 described above.

Here, the communication unit 201 notifies the EMS 130 of the charge amount in the nighttime power calculated by the calculation unit 203 . Then, the EMS 130 transmits a charging instruction including the notified charging amount to the power storage device 110, and the power storage device 110 is supplied by the power system 10 by the charging amount included in the charging instruction during the nighttime period. charge the power.

According to this embodiment, an effect equivalent to that of the first embodiment can be obtained without providing each EMS 130 with a new function.

(Third embodiment)
The third embodiment of the present invention will be described below with reference to FIG. 5, focusing on the differences from the above-described second embodiment.

In general, after the power storage device 110 is fully charged, if all the surplus power of the power generation device 120 is sold, there is no room to respond to the power flow rate control request (down DR). Therefore, there is a problem that a baseline (BL: Base Line) becomes unstable due to fluctuations in the power generated by the power generation device 120 .

Here, the baseline is determined based on the power (consumed power or surplus power of the power generation device 120) for a certain period before the demand response is activated. The adjustment performance (reduced power) when the demand response is activated is obtained from the difference between the baseline and the actual power (power consumption or surplus power of the power generation device 120).

From this point of view, in the present embodiment, not all of the surplus power of the power generation device 120 is used to charge the power storage device 110, but a part of the surplus power of the power generation device 120 is sold (a loss ) to avoid full charging of power storage device 110 .

Specifically, the control unit 204 of the control server 200 determines the charge amount of the power storage device 110 with the surplus power of the power generation device 120 in the facility 100 for a certain period (baseline calculation period) before the demand response is activated. to control. As a result, when the demand response is activated, the chargeable amount of the power storage device 110 in each facility 100 can be secured, and the baseline can be stabilized.

Here, the control server 200 controls the power generation device for a certain period of time before the demand response is activated only when a predetermined condition is satisfied, such as when the chargeable amount of the power storage device 110 in each facility 100 is insufficient. The amount of surplus electric power of 120 charged to the power storage device 110 may be controlled.

Calculation unit 203 calculates power generation device 120 for power storage device 110 to be fully charged at a predetermined time based on power generation prediction information of power generation device 120, past power consumption information during daytime hours, and the remaining amount of power storage device 110. Calculate the charge amount of the surplus power of

Here, the predetermined time may be, for example, the end time of the daytime period, the time of sunset, or the scheduled activation time of the final demand response. For example, if a contract has been concluded with each facility 100 to supply the adjustment capacity of the charge suppression control only until 18:00 and the duration is determined to be 4 hours, the scheduled activation time of the final demand response is 14:00. It's time. That is, the scheduled activation time (predetermined time) of the final demand response is determined based on the time at which the demand response can be activated (that is, the time at which the tidal flow rate control request and the reverse tidal flow rate control request can arrive).

Note that the calculation unit 203 may acquire from the database 202 some or all of the power generation prediction information of the power generation device 120, the past power consumption information in the daytime hours, and the various data of the remaining amount of the power storage device 110. , may be obtained from an external server or the like via the communication unit 201 .

Further, the calculation unit 203 calculates power generation prediction information of the power generation device 120, past power consumption information in the daytime hours, and various data of the remaining amount of the power storage device 110 based on information acquired from the database 202, an external server, or the like. You may

Further, the calculation unit 203 may calculate the charge amount of the surplus power of the power generation device 120 so that the baseline is within a predetermined range for a certain period before the demand response is activated.

Here, the calculation unit 203 calculates the charge amount of the surplus power of the power generation device 120 so that all the surplus power of the power generation device 120 of the facility 100 whose power generation amount is not stable is charged for a certain period before the demand response is activated. may be calculated. As a result, the baseline related to the power storage device 110 of the facility 100 can be stabilized.

Further, the calculation unit 203 may set the achievable range in each facility 100 as the predetermined range.

Furthermore, the calculation unit 203 does not stabilize the baseline related to the power storage device 110 in each facility 100, but the power generation device 120 so as to stabilize the baseline of the entire power storage device 110 in the facility 100 under the control server 200. may be calculated.

Here, the calculation unit 203 may limit the charging amount of the surplus electric power of the power generation device 120 to a certain value equal to or lower than the rated electric power for a certain period before the demand response is activated. According to this feature, the baseline can be stabilized more easily.

An example of the charge/discharge control method according to the present embodiment will be described below with reference to FIG.

In step S<b>201 , the control server 200 acquires power generation prediction information of the power generation device 120 , past power consumption information during daytime hours, and various data of the remaining amount of the power storage device 110 .

In step S202, the control server 200 determines whether or not the chargeable amount of the power storage device 110 in each facility 100 that can meet the demand response is insufficient. If Yes, the operation proceeds to step S203, and if No, the operation ends.

In step S<b>203 , the control server 200 controls the charging amount of surplus electric power of the power generation device 120 in the facility 100 to the power storage device 110 for a certain period before the demand response is activated.

Specifically, the control server 200 calculates the charge amount of surplus power for the power generation device 120 to be fully charged at a predetermined time in a certain period before the demand response is activated, and distributes the charge amount to each facility. 100 EMS 130 are notified. Then, the EMS 130 transmits a charge instruction including the notified charge amount to the power storage device 110, and the power storage device 110 charges the charge amount included in the charge amount for a certain period before the demand response is activated. The surplus power of the power generation device 120 is charged.

According to this embodiment, for a certain period before the demand response is activated, by controlling the amount of surplus power charged to the power storage device 110 of the power generation device 120 in the facility 100, each facility 100 The chargeable amount of the power storage device 110 can be ensured at , and the baseline can be stabilized.

DESCRIPTION OF SYMBOLS 1... Control system 10... Power system 20... Communication network 100... Facility 110... Power storage device 120... Power generation device 130... EMS
DESCRIPTION OF SYMBOLS 131, 201... Communication part 132, 202... Database 133, 203... Calculation part 134, 204... Control part 140... Load 200... Control server

Claims (7)

A power storage device is charged with power supplied by a power system during nighttime hours, and the power storage device is charged with surplus power of a power generation device during daytime hours, and is connected to the power system in response to a request from the power system. A charge/discharge control device capable of controlling a tidal flow rate and a reverse tidal flow rate,
a calculation unit that calculates the charge amount in the nighttime period based on the weather forecast information for the next day, the past power consumption information in the daytime period, and the remaining amount of the power storage device;
A charge/discharge control device, comprising: a control unit configured to charge the power storage device with the electric power corresponding to the calculated charging amount in the nighttime period during the nighttime period. 2. The charge/discharge control device according to claim 1, wherein said calculation unit further calculates the amount of charge in said nighttime period based on prediction information of power consumption for the next day. A power storage device is charged with power supplied by a power system during nighttime hours, and the power storage device is charged with surplus power of a power generation device during daytime hours, and is connected to the power system in response to a request from the power system. A charge/discharge control device capable of controlling a tidal flow rate and a reverse tidal flow rate,
Based on the power generation prediction information of the power generation device, the past power consumption information in the daytime period, and the remaining amount of the power storage device, the charging amount of the surplus power for the power storage device to be fully charged at a predetermined time is calculated. a calculating unit for calculating;
a control unit configured to charge the power storage device with the surplus power by the calculated charge amount of the surplus power for a certain period of time before the request arrives. 4. The charge/discharge control device according to claim 3, wherein said predetermined time is determined based on a time when said request can arrive. The charge/discharge control device according to claim 3 or 4, wherein the calculation unit calculates the charge amount of the surplus power so that a baseline determined based on the power for the certain period of time falls within a predetermined range. The charge/discharge control device according to claim 3 or 4, wherein the calculation unit limits the charge amount of the surplus power to a fixed value equal to or less than the rated power during the fixed period. A step A of controlling the power flow rate and the reverse power flow rate between the power system in response to a request from the power system;
A step B of charging the power storage device with power supplied by the power system during the nighttime period;
A step C of charging the power storage device with surplus power of the power generation device during daytime hours;
a step D of calculating the charge amount in the nighttime period based on the weather forecast information for the next day, the past power consumption information in the daytime period, and the remaining amount of the power storage device;
The charging/discharging control method, wherein in the step C, in the nighttime period, the power storage device is controlled to be charged with the electric power corresponding to the charging amount in the nighttime period calculated in the step D.

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