JP7151570B2 - power controller - Google Patents

Description

The present invention relates to power control devices.

2. Description of the Related Art Conventionally, as described in Patent Literature 1, a power control device that creates a charge/discharge plan for a power storage device installed in a building is known.

JP 2017-79564 A

In the charge/discharge plan created by the power control device described in Patent Document 1, the power storage device is charged during the time period of the day when the electricity rate is low, and when the electricity rate is high in the day, the power storage device is charged. The power storage device discharges in response to . However, since charging efficiency and discharging efficiency differ for each battery due to specifications and manufacturing variations of the batteries mounted on the power storage device, the amount of grid power used to charge the power storage device may increase. This can result in higher electricity bills. Here, the charging efficiency is the ratio of the amount of electric power charged to the power storage device to the amount of power supplied to the power storage device from the system power source. Further, the discharge efficiency is the ratio of the amount of power supplied to the power consuming equipment in the building to the amount of power generated by the discharge of the power storage device.

For example, when the charging efficiency of the power storage device is low, the ratio of the amount of power charged to the power storage device to the amount of power supplied to the power storage device from the grid power source is small. The amount of grid power used for charging the power storage device increases. Therefore, if the charging efficiency of the power storage device is low, the electricity bill will be high. In addition, when the discharge efficiency of the power storage device is low, the ratio of the amount of power supplied to the power consumption device to the amount of power generated by the discharge of the power storage device is small. The amount of discharge power consumed to compensate for the power consumption increases. When the amount of discharge power consumed increases, the amount of power used to charge the power storage device increases, so the amount of grid power used to charge the power storage device increases. Therefore, when the discharge efficiency of the power storage device is low, the electricity bill becomes high.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power control device capable of suppressing an increase in electricity charges.

In order to achieve the above object, the invention described in claim 1 provides power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by a power generation device (21) installed in a building (20). A power generation forecasting unit (S102) that creates, and a consumption forecasting unit (S103) that creates consumption forecast data (Dcf) that is a forecast of changes in the amount of power consumed by the power consumption equipment (24) installed in the building. , power generation prediction data, consumption prediction data, charging/discharging device for electric energy (Ws2) supplied from system power source (11) to charging/discharging device (40) for charging/discharging battery (31) of power storage device (30) System supply ratio (ηs), which is the ratio of the amount of electric power (Ws3) supplied to the battery from the charging/discharging device A plan creation unit (S105) that creates a battery charging/discharging plan (Pcd) based on the charging efficiency (ηc1), and the amount of electric power ( a charging correction unit (S111) for correcting the charging efficiency when the plan creation unit creates a charge/discharge plan based on the ratio (ηc1) of the electric energy (Wc) charged in the battery to Ws3) It is a control device.
Further, the invention described in claim 2 is a power generation prediction unit that creates power generation prediction data (Dgf) that is a prediction of changes in the amount of power generated by a power generation device (21) installed in a building (20). (S102); a consumption forecasting unit (S103) that creates consumption forecast data (Dcf) that is a forecast of changes in the amount of power consumed by the power consuming equipment (24) placed in the building; power generation forecast data; Consumption prediction data, the amount of electric power (Ws2) supplied from the system power source (11) to the charging/discharging device (40) that charges and discharges the battery (31) of the power storage device (30), and the amount of power supplied from the charging/discharging device to the battery. system supply rate (ηs), which is the ratio of the amount of electric power (Ws3) that is charged to the battery, and charging efficiency ( ηc1), a plan creation unit (S105) that creates a battery charging/discharging plan (Pcd), and a charging a supply correction unit (S111) for correcting the system supply rate when the plan creation unit creates the charge/discharge plan based on the ratio (ηs) of the electric energy (Ws3) supplied from the discharge device to the battery. A power controller.
Furthermore, the invention described in claim 3 is a power generation prediction unit that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20). (S102); a consumption forecasting unit (S103) that creates consumption forecast data (Dcf) that is a forecast of changes in the amount of power consumed by the power consuming equipment (24) placed in the building; power generation forecast data; Consumption prediction data, the amount of electric power (Ws2) supplied from the system power source (11) to the charging/discharging device (40) that charges and discharges the battery (31) of the power storage device (30), and the amount of power supplied from the charging/discharging device to the battery. system supply rate (ηs), which is the ratio of the amount of electric power (Ws3) that is charged to the battery, and charging efficiency ( ηc1), a plan creation unit (S105) that creates a battery charging/discharging plan (Pcd), a temperature reading unit (S101) that reads the charging efficiency based on the battery temperature (Tb), and a battery charging The amount of electric power (Wc ), and a temperature correction unit (S111) that corrects the relationship between the temperature of the battery and the charging efficiency based on the ratio (ηc1) of ).

This allows the power control device to create a charging/discharging plan for charging the battery when the grid supply rate and charging efficiency are high. By allowing the battery to charge when the grid availability and charging efficiency are high, less grid power is used to charge the battery than when the grid availability and charging efficiency are low. Therefore, the power control device can reduce the electricity bill and suppress an increase in the electricity bill.

In order to achieve the above object, the invention described in claim 5 provides power generation forecast data (Dgf ) and a consumption prediction unit (S103 ), power generation prediction data, consumption prediction data, and electric power amount (Wd) discharged by the battery (31) of the power storage device (30), the electric power amount supplied from the battery to the charging/discharging device (40) that charges and discharges the battery. Discharge efficiency (ηd), which is the ratio of (Wd1), and discharge supply, which is the ratio of the amount of power (Wd2) supplied from the charging/discharging device to the power consumption device with respect to the amount of power (Wd1) supplied from the battery to the charging/discharging device A plan creation unit (S105) that creates a battery charging/discharging plan based on the rate (ηm), and a battery- discharged power amount (Wd) supplied from the battery to the charging/discharging device when the battery is discharged. and a discharge correction unit (S111) that corrects the discharge efficiency when the plan creation unit creates the charge/discharge plan based on the ratio (ηd) of the electric energy (Wd1) .
Furthermore, the invention recited in claim 6 is a power generation prediction unit that creates power generation prediction data (Dgf) that is a prediction of changes in the amount of power generated by the power generation device (21) installed in the building (20). (S102); a consumption forecasting unit (S103) that creates consumption forecast data (Dcf) that is a forecast of changes in the amount of power consumed by the power consuming equipment (24) placed in the building; power generation forecast data; Consumption prediction data, ratio of electric energy (Wd1) supplied from the battery to the electric energy (Wd) discharged by the battery (31) of the electric storage device (30) to the charging/discharging device (40) for charging and discharging the battery Based on the discharge efficiency (ηd) and the discharge supply rate (ηm), which is the ratio of the amount of power (Wd2) supplied from the charge/discharge device to the power consumption device to the amount of power (Wd1) supplied from the battery to the charge/discharge device a plan creation unit (S105) for creating a battery charging/discharging plan; A power control device comprising a supply correction unit (S111) that corrects a discharge supply rate when a plan creation unit creates a charge/discharge plan based on a ratio (ηm) of an electric energy (Wd2).
Further, the invention recited in claim 7 is a power generation prediction unit that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20). (S102); a consumption forecasting unit (S103) that creates consumption forecast data (Dcf) that is a forecast of changes in the amount of power consumed by the power consuming equipment (24) placed in the building; power generation forecast data; Consumption prediction data, ratio of electric energy (Wd1) supplied from the battery to the electric energy (Wd) discharged by the battery (31) of the electric storage device (30) to the charging/discharging device (40) for charging and discharging the battery Based on the discharge efficiency (ηd) and the discharge supply rate (ηm), which is the ratio of the amount of power (Wd2) supplied from the charge/discharge device to the power consumption device to the amount of power (Wd1) supplied from the battery to the charge/discharge device , a plan creating unit (S105) for creating a battery charging/discharging plan, a temperature reading unit (S101) for reading the discharge efficiency based on the battery temperature (Tb), and a battery temperature acquired when the battery is discharged Based on the ratio (ηd) of the amount of power (Wd1) supplied from the battery to the charging/discharging device to the amount of power (Wd) discharged by the battery corresponding to the temperature and the temperature of the battery obtained when the battery is discharged, and a temperature correction unit (S111) that corrects the relationship between battery temperature and discharge efficiency.

This allows the power control device to create a charge/discharge plan that prohibits battery discharge when the discharge efficiency and discharge supply rate are low. By inhibiting the discharge of the battery when the discharge efficiency and the discharge supply rate are low, an increase in the discharge power amount used to make up for the power shortage is suppressed. For this reason, an increase in the system power amount used for charging for the consumed discharge power amount is suppressed, so an increase in the electricity rate is suppressed.

The reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a configuration diagram of a power management system using the power control device of the embodiment; FIG. FIG. 2 is a relationship diagram showing an efficiency map of the power control device of the embodiment; FIG. 2 is a relationship diagram showing time, power purchase price, and power selling price used in the power control apparatus of the present embodiment; 4 is a flowchart for explaining the processing of the power control device according to the embodiment; FIG. 4 is a diagram showing power generation prediction data and consumption prediction data created by the power control device of the present embodiment; FIG. 4 is a diagram showing a charge/discharge plan when excess/deficiency data and provisional values created by the power control device of the present embodiment are initial values; FIG. 4 is a diagram showing a charge/discharge plan in which surplus/deficiency data and discharge permission times created by the power control device of the present embodiment are set; FIG. 4 is a diagram for explaining correction of an efficiency map by the power control device according to the embodiment; The relationship diagram which shows the efficiency map of the power control apparatus of other embodiment. The figure which shows the charging/discharging plan of the power control apparatus of other embodiment. The figure which shows the charging/discharging plan of the power control apparatus of other embodiment.

The power control device 50 of this embodiment is used in the power management system 100 . First, this power management system 100 will be described.

The power management system 100 manages power in the house 20 while supplying power between the house 20 corresponding to the building and the electric vehicle 30 corresponding to the power storage device via the charging/discharging device 40 . Specifically, the power management system 100 includes a grid power source 11, a grid power line 12, a house 20, an electric vehicle 30, a charging/discharging device 40, a weather server 45, a communication network 46, a power control device 50, and an information server 60. .

The house 20 includes a power generation device 21, an in-house power line 22, a distribution board 23, a power consumption device 24, a system power meter 25, a power generation meter 26, a home-side charge meter 27, a home-side discharge meter 28, and equipment power. A meter 29 is provided.

The power generation device 21 is, for example, a solar power generation device, and is arranged on the roof of the house 20 . The power generator 21 converts the energy of sunlight into electric power. The electric power converted by this power generator 21 is supplied to the distribution board 23 via the indoor power line 22 .

The distribution board 23 receives power transmitted from the system power source 11 via the system power line 12 and power transmitted from the power generator 21 via the indoor power line 22 . Then, the distribution board 23 supplies the electric power supplied from the system power source 11 and the power generation device 21 to the power consumption device 24 and the charging/discharging device 40 to be described later via the indoor power line 22 . In addition, the distribution board 23 supplies power supplied from the battery 31 of the electric vehicle 30 to be described later via the charging/discharging device 40 to the power consuming device 24 via the indoor power line 22 .

The power consumption device 24 is, for example, an air conditioner, a refrigerator, a water heater, or the like, and operates with power from the distribution board 23 .

The system power meter 25 , the power generation meter 26 , the residential charge meter 27 , the residential discharge meter 28 , and the device power meter 29 are arranged in the distribution board 23 . The system power meter 25 measures the amount of power supplied from the system power source 11 to the distribution board 23 via the system power line 12 . The power generation meter 26 measures the amount of power supplied from the power generator 21 to the distribution board 23 via the indoor power line 22 . Residential charge meter 27 measures the amount of power supplied from distribution board 23 to charge/discharge device 40 via home power line 22 . Residential discharge meter 28 measures the amount of power supplied from charge/discharge device 40 to distribution board 23 via home power line 22 . The device watt-hour meter 29 measures the amount of power supplied from the distribution board 23 to the power consuming device 24 via the indoor power line 22 .

The electric vehicle 30 includes a battery 31, a battery temperature sensor 32, a battery control section 33, and the like.

The battery 31 is a chargeable/dischargeable secondary battery, such as a nickel metal hydride battery or a lithium ion battery. This battery 31 is used for a motor that rotates the wheels of an electric vehicle 30 (not shown), and the capacity of the battery 31 is relatively large.

Battery temperature sensor 32 outputs a detection signal corresponding to battery temperature Tb of battery 31 to battery control unit 33 .

The battery control unit 33 is mainly composed of a microcomputer or the like, and includes a CPU, a ROM, a RAM, an I/O, and a bus line or the like for connecting these components. Further, the battery control unit 33 has an interface for communicating with the charging/discharging device 40, which will be described later. Further, the ROM of the battery control unit 33 stores a program executed by the battery control unit 33, the vehicle identification number ID of the electric vehicle 30, and the vehicle type of the electric vehicle 30. FIG.

Further, the battery control unit 33 monitors the battery 31 by estimating the remaining battery capacity SOC of the battery 31 when executing the program stored in the ROM. For example, the battery control unit 33 estimates the remaining battery capacity SOC based on the open circuit voltage OCV of the battery 31 measured by a voltage measuring device (not shown). Then, battery control unit 33 calculates charge power amount Wc and discharge power amount Wd based on the estimated change in remaining battery capacity SOC. The charging power amount Wc is the amount of power charged in the battery 31, and is the amount of increase in the remaining battery capacity SOC when the battery 31 is supplied with power. The discharged power amount Wd is the amount of power generated by discharging the battery 31, and is the amount of decrease in the remaining battery capacity SOC when the battery 31 is discharged.

The charging/discharging device 40 is arranged outside the house 20 and charges/discharges the battery 31 of the electric vehicle 30 . Specifically, the charge/discharge device 40 includes a charge/discharge cable 41 , a device-side charge meter 42 , a device-side discharge meter 43 , and a charge/discharge controller 44 . In addition, charge and discharge shall show both charge and discharge here.

The charging/discharging cable 41 is connected to an inlet of the electric vehicle 30 (not shown), and includes a power line for transferring electric power to and from the battery 31 and a communication line for communicating between the battery control unit 33 and the charging/discharging control unit 44. and

Device-side charge meter 42 and device-side discharge meter 43 are arranged in charging/discharging device 40 . The device-side charge meter 42 measures the amount of power supplied from the charging/discharging device 40 to the battery 31 via the charging/discharging cable 41 . The device-side discharge meter 43 measures the amount of power supplied from the battery 31 to the charging/discharging device 40 via the charging/discharging cable 41 .

The charge/discharge control unit 44 is mainly composed of a microcomputer or the like, and includes a CPU, a ROM, a RAM, an I/O, and a bus line connecting these components. The charge/discharge control unit 44 also has an interface for communicating with the battery control unit 33 .

In addition, when the charge/discharge control unit 44 executes the program stored in the ROM, the charge/discharge control unit 44 acquires the electric energy measured by the device-side charge meter 42 and the device-side discharge meter 43 . Further, the charge/discharge control unit 44 acquires the vehicle identification number ID, the vehicle type, the remaining battery level SOC, the charge power amount Wc, the discharge power amount Wd, and the battery temperature Tb from the battery control unit 33 via the charge/discharge cable 41. .

The weather server 45 creates weather forecast data Dwf, which is a forecast of changes in the weather and amount of sunshine for each predetermined period. The prepared weather forecast data Dwf is transmitted to power control device 50 via communication network 46 .

The power control device 50 is arranged inside the house 20 . The power control device 50 is mainly composed of a microcomputer or the like, and includes a CPU, a ROM, a RAM, an I/O, and a bus line or the like for connecting these components. The power control device 50 also has an interface for communicating with the system power meter 25 , the power generation meter 26 , the residential charge meter 27 , the residential discharge meter 28 and the equipment power meter 29 . Further, power control device 50 includes an interface for communicating with charge/discharge control unit 44 and an interface for communicating with weather server 45 and information server 60 (to be described later) via communication network 46 .

Specifically, the power control device 50 has a power generation prediction unit 51, a consumption prediction unit 52, an excess/deficiency prediction unit 53, a plan creation unit 54, and a power control unit 55 as functional control blocks. The power control device 50 also has a map generator 57 corresponding to the effective efficiency calculator 56 and the charge corrector, discharge corrector, and supply corrector.

Based on the weather forecast data Dwf obtained from the weather server 45 via the communication network 46, the power generation forecasting unit 51 generates power generation forecast data Dgf that predicts changes in the amount of power generated by the power generator 21 for each predetermined period. to create

The consumption prediction unit 52 creates consumption prediction data Dcf that is a prediction of changes in the amount of power consumed by the power consumption device 24 for each predetermined period.

The excess/deficiency prediction unit 53 creates excess/deficiency data Ded, which is a prediction of the transition of the shortage of the amount of electric power generated by the power generation device 21 for each predetermined period, based on the power generation prediction data Dgf and the consumption prediction data Dcf. .

The plan creation unit 54 is a charge/discharge plan for charging/discharging the battery 31 based on the remaining battery SOC of the battery 31, excess/deficiency data Ded, an efficiency map Me, and an electricity purchase price Cp and an electricity sale price Cs, which will be described later. Create Plan Pcd. In addition, the plan creation unit 54 creates a charge/discharge plan Pcd that reduces the electricity bill. The details of the creation of this charge/discharge plan Pcd will be described later.

The power control unit 55 transmits a signal for charging/discharging the battery 31 according to the charging/discharging plan Pcd to the charging/discharging control unit 44 . Based on the signal transmitted from the power control unit 55 , the charge/discharge control unit 44 charges and discharges the battery 31 according to the charge/discharge plan Pcd created by the plan creation unit 54 .

The actual efficiency calculation unit 56 calculates the system power meter 25, the generated power meter 26, the residential charge meter 27, the residential discharge meter 28, the device power meter 29, the device charge meter 42, and the device discharge. Each power efficiency is calculated based on the amount of power measured by the total 43 .

The map generator 57 corrects the efficiency map Me, which is the relationship between each power amount and each power efficiency. Then, the map creation unit 57 associates the corrected efficiency map Me with the vehicle identification number ID and the vehicle type of the electric vehicle 30, and transmits it to the information server 60, which will be described later, via the communication network . The details of each power efficiency, the efficiency map Me, and the correction of the efficiency map Me will be described later.

The information server 60 accumulates the efficiency map Me obtained from the power control device 50 via the communication network 46 .

The power management system 100 is configured as described above. Next, the details of each power efficiency and the efficiency map Me will be described in order to explain the creation of the charging/discharging plan Pcd for reducing the electricity bill by the power control device 50 .

Here, for convenience of explanation, terms are defined as follows. The amount of power measured by the generated power meter 26 and supplied from the power generator 21 to the distribution board 23 via the indoor power line 22 is assumed to be the generated power amount Wg. A surplus power amount We is defined as a power amount surplus when the power generated by the power generation device 21 is used by the power consumption device 24 in the power generation amount Wg. A first surplus power amount We1 is defined as the power amount to be sold out of the surplus power amount We. Among the surplus electric energy We measured by the residential charge meter 27, the electric energy supplied from the distribution board 23 to the charging/discharging device 40 via the indoor power line 22 is defined as a second surplus electric energy We2. Of the second surplus power We2 measured by the device-side charge meter 42, the power supplied from the charging/discharging device 40 to the battery 31 via the charging/discharging cable 41 is referred to as a third surplus power We3.

In addition, the power shortage Wi when the power generated by the power generation device 21 is used by the power consumption device 24 is defined as the power shortage Wi. The amount of power supplied from the system power source 11 to the distribution board 23 via the system power line 12 is assumed to be a system power amount Ws. Of the system power amount Ws, the power amount supplied from the distribution board 23 to the power consumption device 24 via the indoor power line 22 is defined as a first system power amount Ws1. Of the system power amount Ws, the power amount supplied from the distribution board 23 to the charging/discharging device 40 via the indoor power line 22 is referred to as a second system power amount Ws2. Of the second system power amount Ws2, the power amount supplied from the charging/discharging device 40 to the battery 31 via the charging/discharging cable 41 is assumed to be a third system power amount Ws3.

Further, the amount of electric power supplied from the battery 31 to the charging/discharging device 40 via the charging/discharging cable 41 out of the discharged electric power amount Wd is defined as a first discharge supply amount Wd1. Of the first discharge supply amount Wd1, the amount of power supplied from the charging/discharging device 40 to the distribution board 23 via the indoor power line 22 is defined as a second discharge supply amount Wd2. Of the second discharge supply amount Wd2, the amount of power supplied from the distribution board 23 to the power consumption device 24 via the indoor power line 22 is assumed to be a third discharge supply amount Wd3. Here, the power control device 50 regards the power loss due to the distribution board 23 as zero. Thereby, the power control device 50 considers the second discharge supply amount Wd2 to be equal to the third discharge supply amount Wd3. In addition, in FIG. 1, each flow of electric power from the grid power source 11 is indicated by a solid line arrow in order to clarify each amount of electric power. Also, each flow of electric power from the power generator 21 is indicated by a dashed line. Furthermore, each flow of electric power from the battery 31 is indicated by a dashed line.

Also, the ratio of the third system power amount Ws3 to the second system power amount Ws2 is defined as a system supply rate ηs. The ratio of the third surplus power amount We3 to the second surplus power amount We2 is assumed to be the power generation supply rate ηg. The ratio of the charging power amount Wc to the third system power amount Ws3 is assumed to be the first charging efficiency ηc1 of the battery 31 . A ratio of the charging power amount Wc to the third surplus power amount We3 is defined as a second charging efficiency ηc2 of the battery 31 . The ratio of the first discharge supply amount Wd1 to the discharge power amount Wd is defined as the discharge efficiency ηd of the battery 31 . A ratio of the second discharge supply amount Wd2 to the first discharge supply amount Wd1 is defined as a discharge supply rate ηm.

Each power efficiency is a system supply rate ηs, a power generation supply rate ηg, a first charging efficiency ηc1, a second charging efficiency ηc2, a discharge efficiency ηd, and a discharge supply rate ηm. - (1-6).

ηs=Ws3/Ws2 (1-1)
ηg=We3/We2 (1-2)
ηc1=Wc/Ws3 (1-3)
ηc2=Wc/We3 (1-4)
ηd=Wd1/Wd (1-5)
ηm=Wd2/Wd1 (1-6)

The efficiency map Me is, as shown in FIG. 2, the corresponding electric energy, system supply rate ηs, generation supply rate ηg, first charge efficiency ηc1, second charge efficiency ηc2, discharge efficiency ηd, and discharge supply rate ηm. and is a relational diagram of each.

Here, as shown in FIG. 2, the system supply rate ηs increases as the power amount corresponding to the system supply rate ηs, that is, the second system power amount Ws2 increases. As the amount of power corresponding to the power generation supply rate ηg, that is, the second surplus power amount We2 increases, the power generation supply rate ηg increases. As the power amount corresponding to the first charging efficiency ηc1, that is, the third system power amount Ws3 increases, the first charging efficiency ηc1 increases. The second charging efficiency ηc2 increases as the amount of power corresponding to the second charging efficiency ηc2, that is, the third surplus power amount We3 increases. As the amount of power corresponding to the discharge efficiency ηd, that is, the amount of discharge power Wd increases, the discharge efficiency ηd increases. As the electric energy corresponding to the discharge supply rate ηm, that is, the first discharge supply amount Wd1 increases, the discharge supply rate ηm increases. Also, the first charging efficiency ηc1 and the second charging efficiency ηc2 are the efficiencies of electric power exchanged between the electric vehicle 30 and the charging/discharging device 40, respectively, and thus have the same relationship. Furthermore, the discharge efficiency ηd has the same relationship as the first charge efficiency ηc1 and the second charge efficiency ηc2. Further, since the system supply rate ηs, the power generation supply rate ηg, and the discharge supply rate ηm are the efficiencies of power exchanged between the distribution board 23 and the charging/discharging device 40, respectively, they have the same relationship. .

Also, in the efficiency map Me, the system supply rate ηs is shown as a function of the second system power amount Ws2. The power generation supply rate ηg is shown as a function of the second surplus power amount We2. The first charging efficiency ηc1 is shown as a function of the third system power amount Ws3. The second charging efficiency ηc2 is shown as a function of the third surplus power amount We3. The discharge efficiency ηd is shown as a function of the discharge power amount Wd. The discharge supply rate ηm is shown as a function of the first discharge supply amount Wd1.

As described above, in the power control device 50, in order to create the charge/discharge plan Pcd, the system supply rate ηs, the power generation supply rate ηg, the first charge efficiency ηc1, the second charge efficiency ηc2, the discharge efficiency ηd, the discharge supply rate ηm and efficiency map Me are used. Next, the calculation of the electricity bill will be described in order to explain the creation of the charging/discharging plan Pcd for reducing the electricity bill by the power control device 50. FIG.

First, the power purchase price Cp and the power selling price Cs for calculating the electricity rate will be described. Here, the power purchase price Cp is the price per unit power amount when the power transmitted from the system power source 11 is used. Moreover, the power selling price Cs is the price per unit power amount when the surplus power of the power generation device 21 is purchased by an electric power company or the like. The power purchase price Cp and the power selling price Cs are set, for example, as shown in FIG. In FIG. 3, the power purchase price Cp is indicated by a solid line, and the power selling price Cs is indicated by a one-dot chain line.

As shown in FIG. 3, the power purchase price Cp is the lowest during the time period from 0:00 to 7:00 in a day. Moreover, the power purchase price Cp is highest during the time period from 7:00 to 17:00 in a day. Furthermore, the power purchase price Cp is higher than the power purchase price Cp in the time period from 00:00 to 7:00 in the time period from 17:00 to just before 24:00 in the day. The price is lower than the power purchase price Cp in the time period from 17:00 to 17:00.
The power selling price Cs is higher than the power buying price Cp in the time period from 17:00 to 24:00 and is lower than the price in the time period from 7:00 to 17:00, and is uniform. For the sake of convenience, the time period from 00:00 to 7:00 in a day is hereinafter referred to as the cheapest time period TM_min. Also, in the figure, the time slot from 7:00 to 17:00 in a day is described as the maximum time slot TM_max. Further, in the figure, the time period from 00:00 to 24:00 in a day is described as middle time period TM_mid.

Then, the calculation of the electricity rate will be explained. Here, the electricity rate is a rate considering both the rate obtained by selling power and the rate paid to the electric power company by purchasing power. For example, the electricity rate is calculated by subtracting the rate obtained by selling power from the rate paid to the electric power company by purchasing power.

First, the charge obtained by selling power is calculated, for example, by multiplying the sold surplus power amount We, that is, the first surplus power amount We1, by the power selling price Cs.

Here, if the ratio of the amount of electric power sold to the surplus electric power We is defined as a power sales ratio α, the surplus electric power We, the first surplus electric power We1, and the power sales ratio α are expressed by the following relational expression (2-1) is represented as

Therefore, if the charge obtained by selling power is Fs, the charge obtained by selling power is a charge obtained by multiplying the first surplus power amount We1 by the power selling price Cs. Using the electricity selling price Cs, it is represented by the following relational expression (2-2).

We1=α×We (2-1)
Fs = We1 x Cs
=α×We×Cs (2-2)

Next, the charge to be paid to the electric power company for power purchase is calculated, for example, by multiplying the system power amount Ws used by the power purchase price Cp. Here, the system power amount Ws used is the sum of the first system power amount Ws1 and the second system power amount Ws2. As described above, the first system power amount Ws1 is the amount of power supplied from the distribution board 23 to the power consumption device 24 via the indoor power line 22 in the system power amount Ws. The second system power amount Ws2 is the amount of power supplied from the distribution board 23 to the charging/discharging device 40 via the indoor power line 22 in the system power amount Ws.

Further, as shown in FIG. 1, the first system power amount Ws1 is used together with the third discharge supply amount Wd3 to make up for the power shortage Wi. The third discharge supply amount Wd3 is the amount of power supplied from the distribution board 23 to the power consumption device 24 via the indoor power line 22, as described above. Further, since the power control device 50 regards the power loss due to the distribution board 23 as zero, it regards the third discharge supply amount Wd3 to be equal to the second discharge supply amount Wd2.

Therefore, the first system power amount Ws1 is calculated by subtracting the third discharge supply amount Wd3 from the power shortage Wi, that is, by subtracting the second discharge power supply Wd2 from the power shortage Wi.

As described above, the second discharge supply amount Wd2 is the amount of electric power supplied from the charging/discharging device 40 to the distribution board 23 via the indoor power line 22 among the first discharge supply amount Wd1. Furthermore, the first discharge supply amount Wd1 is the amount of electric power supplied from the battery 31 to the charging/discharging device 40 via the charging/discharging cable 41 .

Further, when the discharged power of battery 31 is supplied to charging/discharging device 40 via charging/discharging cable 41 , power loss occurs due to electric vehicle 30 and charging/discharging device 40 . Furthermore, the power supplied from charging/discharging device 40 to distribution board 23 via indoor power line 22 causes power loss due to charging/discharging device 40 .

Therefore, the second discharge supply amount Wd2 is calculated by multiplying the discharge power amount Wd by the discharge efficiency ηd and the discharge supply rate ηm. Therefore, the second discharge supply amount Wd2 is represented by the following relational expression (2-3).

Therefore, since the first system power amount Ws1 is calculated by subtracting the second discharge supply amount Wd2 from the power shortage Wi, it is represented by the following relational expression (2-4).

Wd2=Wd×ηd×ηm (2-3)
Ws1=Wi-Wd2
=Wi−Wd×ηd×ηm (2-4)

With respect to the first system power amount Ws1, the second system power amount Ws2 is used to charge the battery 31 together with the second surplus power amount We2. Therefore, the sum of the amount of power charged in the battery 31 out of the second system power amount Ws2 and the amount of power charged in the battery 31 out of the second surplus power amount We2 becomes the charge power amount Wc. The second surplus power amount We2 is the amount of power supplied from the distribution board 23 to the charging/discharging device 40 via the indoor power line 22, out of the surplus power amount We, as described above. Further, the second surplus power amount We2 is expressed by the following relational expression (2-5) using the power selling ratio α and the surplus power amount We.

Further, when power from grid power source 11 is supplied to charging/discharging device 40 via indoor power line 22 and distribution board 23 , power loss occurs due to charging/discharging device 40 . Furthermore, when electric power is supplied from charging/discharging device 40 to battery 31 via charging/discharging cable 41 and battery 31 is charged, power loss occurs due to electric vehicle 30 and charging/discharging device 40 .

Therefore, of the second system power amount Ws2, the amount of power charged to the battery 31 is calculated by multiplying the second system power amount Ws2 by the system supply rate ηs and the charging efficiency ηc. Therefore, of the second system power amount Ws2, the power amount charged to the battery 31 is represented by the following relational expression (2-6). Note that, in the relational expression, the amount of power charged to the battery 31 out of the amount of power Ws2 of the second system is written as Wc1.

Further, when surplus power from power generation device 21 is supplied to charging/discharging device 40 via indoor power line 22 and distribution board 23 , power loss occurs due to charging/discharging device 40 . Furthermore, when electric power is supplied from charging/discharging device 40 to battery 31 via charging/discharging cable 41 and battery 31 is charged, power loss occurs due to electric vehicle 30 and charging/discharging device 40 .

Therefore, of the second surplus power We2, the amount of power charged to the battery 31 is calculated by multiplying the second surplus power We2 by the power generation supply rate ηg and the charging efficiency ηc. As a result, the amount of electric power charged to the battery 31 out of the second surplus electric power amount We2 is represented by the following relational expression (2-7). Note that, in the relational expression, the amount of power charged to the battery 31 out of the second surplus amount of power We2 is written as Wc2.

Therefore, since the charging power amount Wc is the sum of Wc1 and Wc2, it is represented by the following relational expression (2-8). As a result, the second system power amount Ws2 is represented by the following relational expression (2-9).

We2=(1-α)×We (2-5)
Wc1=Ws2×ηs×ηc1 (2-6)
Wc2=We2×ηg×ηc2 (2-7)
Wc=Wc1+Wc2
=Ws2×ηs×ηc1+We2×ηg×ηc2 (2-8)
Ws2=(Wc−We2×ηg×ηc2)/(ηs×ηc1)
... (2-9)

As described above, the first system power amount Ws1 and the second system power amount Ws2 are calculated. The charge paid to the electric power company for power purchase is calculated by multiplying the sum of the first system power amount Ws1 and the second system power amount Ws2 by the power purchase price Cp. 10). Also, the second surplus power amount We2 shown in the relational expression (2-10) is expressed by the power selling ratio α and the surplus power amount We using the above relational expression (2-5). Therefore, the charge to be paid to the electric power company by purchasing power is expressed by the following relational expression (2-11) using the power selling ratio α and the surplus power amount We. In the relational expression, Fc is the fee paid to the electric power company by purchasing power.

Fc=(Ws1+Ws2)×Cp
= ((Wi−Wd×ηd×ηm)
+ (Wc−We2×ηg×ηc2)/(ηs×ηc1))×Cp
... (2-10)
Fc=((Wi−Wd×ηd×ηm)
+ (Wc-(1-α)×We×ηg×ηc2)/(ηs×ηc1))×Cp
... (2-11)

Therefore, the electricity charge is calculated by subtracting the charge obtained by selling power from the charge paid to the electric power company by purchasing power. It is represented by the following relational expression (2-12). As a result, the electricity rate is calculated based on the power shortage Wi, the discharged power Wd, the charged power Wc, the surplus power We, the power selling ratio α, the power buying price Cp, and the power selling price Cs. Also, the electricity rate is calculated based on the system supply rate ηs, power generation supply rate ηg, first charge efficiency ηc1, second charge efficiency ηc2, discharge efficiency ηd, and discharge supply rate ηm. In the relational expression (2-12), FT represents the electricity rate.

FT=Fc-Fs
= ((Wi−Wd×ηd×ηm)
+ (Wc-(1-α)×We×ηg×ηc2)/(ηs×ηc1))×Cp
-α×We×Cs (2-12)

As described above, an electricity bill is calculated as an example. 4 and the relational diagrams of FIGS. 5 to 8, generation of the charging/discharging plan Pcd for reducing the electricity rate and correction of the efficiency map Me by the power control device 50 will be described.

In step S101, the power control device 50 acquires the weather forecast data Dwf and vehicle information, and reads the efficiency map Me corresponding to the acquired vehicle information. Specifically, power control device 50 acquires weather forecast data Dwf from weather server 45 via communication network 46 . Also, the charge/discharge control unit 44 acquires vehicle information of the electric vehicle 30 connected to the charge/discharge cable 41 from the battery control unit 33 via the charge/discharge cable 41 . The power control device 50 acquires the vehicle information stored in the charge/discharge control unit 44 and reads out the efficiency map Me corresponding to the acquired vehicle information. Here, the vehicle information is the vehicle identification number ID of the electric vehicle 30 , the vehicle type, and the remaining battery capacity SOC of the battery 31 .

Subsequently, in step S102, the power control device 50 creates power generation forecast data Dgf for each predetermined period based on the weather forecast data Dwf. Specifically, the power control device 50 generates power generation prediction data for each predetermined period based on the amount of sunshine for each predetermined period indicated in the weather forecast data Dwf and the power generation performance such as the energy conversion efficiency of the power generation device 21. Create a Dgf. Here, as shown in FIG. 5, during the time period from 7:00 to 17:00, sunlight hits the power generator 21 and the power generator 21 generates power to generate the power generation amount Wg. Here, the predetermined period is defined as a period obtained by dividing one day into 30-minute intervals. In addition, in the power generation prediction data Dgf of FIG. 5, the direction of the arrow on the vertical axis indicating the power generation amount Wg is the positive direction.

Subsequently, in step S103, the power control device 50 generates consumption prediction data Dcf for each predetermined period based on the amount of power measured by the device watt-hour meter 29, that is, the amount of power consumed by the power consuming device 24. create. Specifically, the power control device 50 creates the consumption prediction data Dcf using the transition of the amount of power consumed by the power consuming device 24 in the past and an autoregressive model. Here, as shown in FIG. 5, the power consumed by the power consuming device 24 is from 0:00 to 6:00 and from 21:00 to 24:00 when the user of the house 20 is asleep. The power consumption Wm, which is the planned power amount, is relatively small. Moreover, the power consumption Wm is relatively large in the time period from 6:00 to 21:00 when the users of the house 20 are active. In addition, in the consumption prediction data Dcf of FIG. 5, the direction of the arrow on the vertical axis indicating the power consumption Wm is assumed to be the positive direction.

Subsequently, in step S104, the power control device 50 creates excess/deficiency data Ded for each predetermined period based on the power generation forecast data Dgf and the consumption forecast data Dcf. Specifically, the excess/deficiency prediction unit 53 subtracts the power generation prediction data Dgf from the consumption prediction data Dcf to create the excess/deficiency data Ded. For example, during a period in which the value obtained by subtracting the amount of generated power Wg from the amount of power consumed Wm for the corresponding predetermined period is a positive value, the amount of generated power Wg is insufficient because the amount of power consumed Wm is large. As a result, a shortage of power Wi is generated. Further, in a period in which the value obtained by subtracting the generated power amount Wg from the power consumption Wm in the corresponding predetermined period is a negative value, the generated power amount Wg is large, so the generated power amount Wg is surplus. As a result, a surplus power amount We, which is the amount of power surplus to the generated power amount Wg, is generated. Here, as shown in FIGS. 6 and 7, the power control device 50 subtracts the power generation prediction data Dgf of FIG. 5 from the consumption prediction data Dcf of FIG. 5 to create excess/deficiency data Ded. 6 and 7, the direction of the "+" arrow indicates the positive direction, and the vertical axis on the "+" side indicates the power shortage Wi. The direction of the arrow "-" is the negative direction, and the vertical axis on the "-" side indicates the surplus electric energy We. Moreover, similar excess/deficiency data Ded are described in FIG. 6 and FIG.

Subsequently, in loop L1, the power control device 50 sets a temporary value A, which is a variable indicating a temporary time when the battery 31 reaches full charge, and repeats the processing from step S105 to step S107. Here, the initial value of the provisional value A is set to the end time of the cheapest time period TM_min, which is the time period when the power purchase price Cp is the lowest.

Specifically, in step S105 of loop L1, the power control device 50 creates a charge/discharge plan Pcd corresponding to the current provisional value A. At this time, the power control device 50 creates a charging/discharging plan Pcd for charging the battery 31 and discharging the battery 31 after the provisional value A so as to reduce the electricity rate.

For example, when the provisional value A is the initial value, the time when the battery 31 is fully charged is set to 7:00, which is the end time of the cheapest time period TM_min. At this time, in the time period from 0:00 to 7:00, the surplus electric energy We does not occur, so as shown in FIG. Create a charge/discharge plan Pcd. In the charging/discharging plan Pcd, the direction of the “+” arrow is the positive direction, and the vertical axis on the “+” side indicates the charge power amount Wc to be charged to the battery 31 . The direction of the arrow "-" is the negative direction, and the vertical axis on the "-" side indicates the amount of discharge electric power Wd expected to be generated when the battery 31 is discharged.

Subsequently, in step S106, the power control device 50 calculates the daily electricity rate when charging and discharging the battery 31 along the charging and discharging plan Pcd when the provisional value A is set. Specifically, the power control device 50 calculates the daily electricity bill by integrating the electricity bill for each predetermined period based on the above relational expression (2-12). The electricity rate for each predetermined period is calculated based on the power purchase price Cp, the power selling price Cs, the power shortage Wi, the surplus power We, the charge power Wc, and the discharge power Wd for each predetermined period. Further, the electricity bill for each predetermined period is calculated based on the first charging efficiency ηc1, system supply rate ηs, second charging efficiency ηc2, power generation supply rate ηg, discharge efficiency ηd, discharge supply rate ηm, and electricity sales ratio α for each predetermined period. calculated based on Calculation of each power amount and each power efficiency for each predetermined period when the charging/discharging plan Pcd is planned will be described below.

The power deficit Wi and the surplus power We for each predetermined period are calculated by referring to the excess/deficiency data Ded.

The charging power amount Wc and the discharging power amount Wd for each predetermined period are calculated by referring to the charging/discharging plan Pcd.

The first charging efficiency ηc1 is a value obtained by dividing the charging power amount Wc by the third system power amount Ws3, as expressed by the above relational expression (1-3). Also, the first charging efficiency ηc1 is expressed as a function of the third system power amount Ws3 based on the efficiency map Me read in step S101. Therefore, the third system electric power amount Ws3 is represented by the charging electric power amount Wc as shown in the following relational expression (3-1). As a result, the third system power amount Ws3 is calculated using the charge power amount Wc indicated in the charging/discharging plan Pcd. Therefore, the first charging efficiency ηc1 is calculated by dividing the charging power amount Wc indicated by the charging/discharging plan Pcd by the calculated third system power amount Ws3. In the following relational expressions, "f" indicates a function.

ηc1=Wc/Ws3
=f(Ws3)
Wc=Ws3×f(Ws3) (3-1)

The system supply rate ηs is a value obtained by dividing the third system power amount Ws3 by the second system power amount Ws2, as expressed by the above relational expression (1-1). Further, the system supply rate ηs is expressed as a function of the second system power amount Ws2 based on the efficiency map Me read in step S101. Therefore, the second system power amount Ws2 is represented by the third system power amount Ws3 as shown in the following relational expression (3-2). Thereby, the second system power amount Ws2 is calculated using the third system power amount Ws3 calculated as described above. Therefore, the system supply rate ηs is calculated by dividing the calculated third system power amount Ws3 by the second system power amount Ws2.

ηs=Ws3/Ws2
=f(Ws2)
Ws3=Ws2×f(Ws2) (3-2)

The second charging efficiency ηc2 is a value obtained by dividing the charging power amount Wc by the third surplus power amount We3, as expressed by the above relational expression (1-4). Also, the second charging efficiency ηc2 is expressed as a function of the third surplus power amount We3 based on the efficiency map Me read in step S101. Therefore, the third surplus power amount We3 is represented by the charging power amount Wc as shown in the following relational expression (3-3). Thereby, the third surplus power amount We3 is calculated using the charging power amount Wc indicated in the charging/discharging plan Pcd. Therefore, the second charging efficiency ηc2 is calculated by dividing the charging power amount Wc indicated by the charging/discharging plan Pcd by the calculated third surplus power amount We3.

ηc2=Wc/We3
=f(We3)
Wc=We3×f(We3) (3-3)

The power generation supply rate ηg is a value obtained by dividing the third surplus electric energy We3 by the second surplus electric energy We2, as expressed by the above relational expression (1-2). Further, the power generation supply rate ηg is expressed as a function of the second surplus power amount We2 based on the efficiency map Me read in step S101. Therefore, the second surplus power amount We2 is represented by the third surplus power amount We3 as in relational expression (3-4) below. Thereby, the second surplus power amount We2 is calculated using the third surplus power amount We3 calculated as described above. Therefore, the power generation supply rate ηg is calculated by dividing the calculated third surplus electric energy We3 by the second surplus electric energy We2.

ηg=We3/We2
=f(We2)
We3=We2×f(We2) (3-4)

The discharge efficiency ηd is expressed as a function of the discharge power amount Wd based on the efficiency map Me read out in step S101, as in relational expression (3-5) below. Thereby, the discharge efficiency ηd is calculated using the discharge power amount Wd indicated in the charge/discharge plan Pcd.

ηd=f(Wd) (3-5)

The discharge supply rate ηm is expressed as a function of the first discharge supply amount Wd1 based on the efficiency map Me read in step S101, as in relational expression (3-6) below. Further, the discharge efficiency ηd is a value obtained by dividing the first discharge supply amount Wd1 by the discharge power amount Wd, as expressed by the above relational expression (1-5). Therefore, the first discharge supply amount Wd1 is calculated by multiplying the discharge power amount Wd indicated in the charge/discharge plan Pcd by the discharge efficiency ηd calculated as described above. Therefore, the discharge supply rate ηm is calculated using the calculated first discharge supply amount Wd1.

ηm=f(Wd1) (3-6)

The power selling ratio α is calculated based on the provisional value A and the surplus power amount We. For example, when the temporary value A is the initial value, the surplus power amount We is not used to charge the battery 31, so the power selling ratio α is 1.

Further, the power selling ratio α is the first surplus power amount We1 with respect to the surplus power amount We, as expressed by the above relational expression (2-1). Then, of the surplus electric energy We, the first surplus electric energy We1, which is the electric energy to be sold, is calculated by subtracting the second surplus electric energy We2 calculated as described above from the surplus electric energy We. be done. Therefore, the power sales ratio α is calculated by dividing the calculated first surplus power amount We1 by the surplus power amount We. It should be noted that the power control device 50 cannot sell the surplus power when the first surplus power amount We1 is less than or equal to zero, and therefore considers the power sale ratio α to be zero.

In this way, the power control device 50 calculates the electricity rate for each predetermined period by calculating each amount of power, each power efficiency, the power purchase price Cp, the power selling price Cs, and the power selling ratio α for each predetermined period. do. Then, the power control device 50 integrates the electricity bill for each predetermined period to calculate the electricity bill for one day.

After the electricity rate is calculated in step S106, the power control device 50 sets a value obtained by adding a predetermined time period Δt to the current provisional value A as a new provisional value A in step S107. After that, the process returns to step S105. Here, the predetermined time Δt is assumed to be 30 minutes.

Returning to step S105, the power control device 50 creates a charging/discharging plan Pcd corresponding to the current provisional value A, that is, the provisional value A set in the previous step S107. Note that when the provisional value A changes from the initial value, the power control device 50 creates a charge/discharge plan Pcd for charging the battery 31 using the surplus power amount We when the surplus power amount We is generated. . Therefore, the power control device 50 creates a charging/discharging plan Pcd in which the charging start time and the charging power amount Wc of the battery 31 are adjusted.

Subsequently, in step S106, the power control device 50 charges and discharges the battery 31 in accordance with the current provisional value A, that is, the charging/discharging plan Pcd corresponding to the provisional value A set in the immediately preceding step S107. Calculate the electricity bill for the day.

Subsequently, in step S107, the power control device 50 sets a value obtained by adding a predetermined time period Δt to the current provisional value A as a new provisional value A.

In this way, while changing the provisional value A for a predetermined period of time Δt, the provisional value A is changed from 7:00 when the cheapest time period TM_min ends to 17:00 when power generation by the power generation device 21 ends (step S105). to step S107 are repeated. The processing from step S105 to step S107 is repeated, and the daily electricity bill corresponding to each provisional value A is calculated. Then, when the loop L1 ends, the process proceeds to step S108.

In step S108, the power control device 50 sets the discharge permission time td of the charge/discharge plan Pcd to the time corresponding to the provisional value A when the electricity rate calculated in step S107 is the lowest. Then, as shown in FIG. 7, the power control device 50 selects the charge/discharge plan Pcd when the discharge permission time td is set. Here, as shown in the figure, the discharge permission time td is set to 14:00.

Subsequently, in step S109, power control device 50 generates excess/deficiency data Ded based on excess/deficiency data Ded created in step S104 and charging/discharging plan Pcd selected in step S108, as shown in FIG. Recreate. Specifically, the power control device 50 adds the power amount obtained by multiplying the corresponding charging power amount Wc by the corresponding power efficiency to the corresponding power shortage Wi and surplus power We. In addition, the power control device 50 adds the power amount obtained by multiplying the corresponding discharge power amount Wd by the corresponding power efficiency to the corresponding power shortage Wi and surplus power amount We. In the drawing, the excess/deficiency data Ded to be recreated is described as Ded_R.

Subsequently, in step S110, power control device 50 executes charging/discharging plan Pcd selected in step S108. Specifically, a signal for charging/discharging the battery 31 along the charging/discharging plan Pcd selected in step S108 is transmitted to the charging/discharging control unit 44 . Based on the signal transmitted by the power control unit 55, the charge/discharge control unit 44 causes the battery 31 to be charged/discharged according to the charge/discharge plan Pcd.

Further, when the battery 31 is being charged and discharged according to this charging/discharging plan Pcd, the power control device 50 acquires each electric energy from each watt-hour meter. Specifically, power control device 50 acquires second system power amount Ws<b>2 and second surplus power amount We<b>2 from residential charging meter 27 . The power control device 50 acquires the third system power amount Ws3 and the third surplus power amount We3 from the device-side charging amount meter 42 via the charge/discharge control unit 44 . Power control device 50 acquires charge power amount Wc and discharge power amount Wd from battery control unit 33 via charge/discharge cable 41 and charge/discharge control unit 44 . The power control device 50 acquires the first discharge supply amount Wd1 from the device-side discharge amount meter 43 via the charge/discharge control section 44 . The power control device 50 acquires the second discharge supply amount Wd2 from the residential discharge amount meter 28 . Then, the power control device 50 calculates the system supply rate ηs, the power generation supply rate ηg, the first charging efficiency ηc1, the second charging efficiency ηc2, the discharge efficiency ηd, and the discharge supply rate ηm based on the acquired power amounts. Calculate power efficiency.

Subsequently, in step S111, the power control device 50 calculates the corresponding electric energy, the system supply rate ηs, the generation supply rate ηg, the first charging efficiency ηc1, the second charging efficiency ηc2, and the discharge efficiency ηd calculated in step S110. and the discharge supply rate ηm. Then, the power control device 50 corrects the efficiency map Me using the plotted values. The power control device 50 corrects a function indicating, for example, the system supply rate ηs, the generation supply rate ηg, the charge efficiency ηc, the discharge efficiency ηd, and the discharge supply rate ηm with respect to the electric energy. For example, the power control device 50 regenerates each function by adding each plot point for the currently calculated power amount to each plot point for the power amount calculated and accumulated in the past. In FIG. 8, as an example of correction by the power control device 50, the current first charging efficiency ηc1 is indicated by solid-line white circles, and the past first charging efficiency ηc1 is indicated by broken-line white circles. It is Also, the plotted points of the current system supply rate ηs are indicated by black circles, and the plotted points of the past system supply rate ηs are indicated by triangles. Furthermore, approximate curves of the corrected first charging efficiency ηc1 and system supply rate ηs are shown. In the initial state, the relationship between the amount of power and the system supply rate ηs, generation supply rate ηg, charge efficiency ηc, discharge efficiency ηd, and discharge supply rate ηm is set in advance. These initial values are set through experiments and simulations.

The power control device 50 then transmits the corrected efficiency map Me to the information server 60 together with the vehicle identification number ID and the vehicle type of the electric vehicle 30 . Further, the power control device 50 uses this corrected efficiency map Me for the next charging/discharging plan Pcd. After that, the processing of the power control device 50 ends.

As described above, the processing of the power control device 50 is performed. Then, the fact that the power control device 50 of the present embodiment can suppress an increase in electricity charges will be described.

Power control device 50 creates charging/discharging plan Pcd based on system supply rate ηs and first charging efficiency ηc1. Thereby, power control device 50 can create charging/discharging plan Pcd for charging battery 31 of electric vehicle 30 when system supply rate ηs and first charging efficiency ηc1 are high. When the system supply rate ηs is high, the ratio of the third system power amount Ws3 to the second system power amount Ws2 is large, and when the first charging efficiency ηc1 is high, the ratio of the charged power amount Wc to the third system power amount Ws3 is large. . Therefore, by charging the battery 31 when the system supply rate ηs and the first charging efficiency ηc1 are high, the battery 31 can be charged more than when the system supply rate ηs and the first charging efficiency ηc1 are low. The system power amount Ws to be supplied becomes smaller. Therefore, the power control device 50 can reduce the electricity bill and suppress an increase in the electricity bill.

Here, as shown in FIG. 7, the power control device 50 sets the charging/discharging plan Pcd to increase the charging power amount Wc for each predetermined period in the time slot from 0:00 to 7:00, which is the cheapest time slot TM_min. Creating. Further, the power control device 50 creates a charging/discharging plan Pcd that increases the charging power amount Wc for each predetermined period within the specifications of the charging/discharging device 40 and the battery 31 . In the charge/discharge plan Pcd, when the charge power amount Wc for each predetermined period increases, the second system power amount Ws2 and the third system power amount Ws3 for each predetermined period increase in order to charge the battery 31 .

Further, here, as shown in FIG. 2, the system supply rate ηs increases as the power amount corresponding to the system supply rate ηs, that is, the second system power amount Ws2 increases. Further, as the electric energy corresponding to the first charging efficiency ηc1, that is, the third system electric energy Ws3 increases, the first charging efficiency ηc1 increases.

Therefore, in the time period from 0:00 to 7:00, power control device 50 sets charging power amount Wc at which system supply rate ηs and first charging efficiency ηc1 are at their maximum values. A plan is being created to charge the battery 31 . Since the second system power amount Ws2 and the third system power amount Ws3 for each predetermined period are increased by increasing the charge power amount Wc for each predetermined period, the system supply rate ηs and the first charging efficiency ηc1 are increased. When the system supply rate ηs and the first charging efficiency ηc1 are high, the system power amount Ws used for charging the battery 31 is smaller than when the system supply rate ηs and the first charging efficiency ηc1 are low. Therefore, the electricity bill becomes cheaper, and an increase in the electricity bill is suppressed.

Also, the power control device 50 creates a charge/discharge plan Pcd based on the discharge efficiency ηd and the discharge supply rate ηm. Thereby, power control device 50 can create charge/discharge plan Pcd that prohibits discharge of battery 31 when discharge efficiency ηd and discharge supply rate ηm are low. When the discharge efficiency ηd is low, the ratio of the first discharge supply Wd1 to the discharge power Wd is small, and when the discharge supply rate ηm is low, the ratio of the second discharge supply Wd2 to the first discharge supply Wd1 is small. Therefore, when the discharge efficiency ηd and the discharge supply rate ηm are low, the discharge of the battery 31 is prohibited, thereby suppressing an increase in the discharge power amount Wd used to make up for the power shortage Wi. . For this reason, an increase in the amount of system electric energy Ws used for charging the discharged electric energy Wd consumed is suppressed, so an increase in the electricity rate is suppressed.

Further, power control device 50 creates charge/discharge plan Pcd based on system supply rate ηs, first charge efficiency ηc1, discharge efficiency ηd, discharge supply rate ηm, and power purchase price Cp. Thereby, the power control device 50 can further suppress an increase in the electricity bill.

Here, for example, the electricity bill for charging the electric energy for the discharged electric energy Wd may be higher than the electricity bill for supplementing the electric energy compensated by the discharged electric energy Wd with the first system electric energy Ws1. be. In this case, the electricity bill for charging the battery 31 becomes high, so the user of the house 20 loses the electricity bill. In order to explain how the power control device 50 further suppresses an increase in the electricity bill, the electricity bill for charging the electric energy corresponding to the discharged electric energy Wd and the electric energy compensated by the discharged electric energy Wd will be described below. is supplemented with the first system power amount Ws1.

The electricity charge for charging the electric energy for the discharged electric energy Wd is the power purchase price Cp for charging the battery 31 with the second system electric energy Ws2 for charging the electric energy for the discharged electric energy Wd. Calculated by multiplying. As described above, the second system power amount Ws2 is the amount of power supplied from the distribution board 23 to the charging/discharging device 40 via the indoor power line 22 in the system power amount Ws.

Further, when electric power from system power source 11 is supplied to electric vehicle 30 via charging/discharging device 40 , power loss occurs due to electric vehicle 30 and charging/discharging device 40 .

Therefore, the second system power amount Ws2 for charging the power amount for the discharge power amount Wd is calculated by multiplying the second system power amount Ws2 by the system supply rate ηs and the first charging efficiency ηc1. be. Therefore, the second system power amount Ws2 for charging the power amount corresponding to the discharge power amount Wd is represented by the following relational expression (4-1). As a result, the second system power amount Ws2 is represented by the following relational expression (4-2).

Therefore, the electricity charge for charging the electric energy for the discharged electric energy Wd is calculated by multiplying the second system electric energy Ws2 by the power purchase price Cp for charging the battery 31. It is expressed as in formula (4-3). In addition, in the following relational expression, the electricity charge for charging the electric energy corresponding to the discharged electric energy Wd is described as F1. Also, the power purchase price Cp for charging the battery 31 is described as Cp1.

Wd=Ws2×ηs×ηc1 (4-1)
Ws2=Wd/(ηs×ηc1) (4-2)
F1=Ws2×Cp1
=(Wd/(ηs×ηc1))×Cp1 (4-3)

Subsequently, the electricity charge for supplementing the electric energy compensated by the discharged electric energy Wd with the first system electric energy Ws1 is as follows: It is calculated by multiplying the power purchase price Cp when the As described above, the first system power amount Ws1 is the amount of power supplied from the distribution board 23 to the power consumption device 24 via the indoor power line 22 in the system power amount Ws.

Also, when the discharged power of the battery 31 is supplied to the distribution board 23 via the charging/discharging device 40 , there is power loss due to the electric vehicle 30 and the charging/discharging device 40 .

Therefore, the amount of power to be supplemented with the amount of discharge power Wd, that is, the second discharge supply amount Wd2 is calculated by multiplying the amount of discharge power Wd by the discharge efficiency ηd and the discharge supply rate ηm. Therefore, the second discharge supply amount Wd2 is represented by the above relational expression (2-3).

Since the power control device 50 regards the power loss due to the distribution board 23 as zero, the first system power amount Ws1 corresponding to the power amount compensated by the discharge power amount Wd is equal to the second discharge supply amount Wd2. I reckon.

Therefore, the electricity charge for supplementing the electric energy compensated by the discharge electric energy Wd with the first system electric energy Ws1 is calculated by multiplying the second discharge supply amount Wd2 by the power purchase price Cp for discharging the battery 31. Since it is calculated, it is represented by the following relational expression (4-4). That is, the electricity charge for supplementing the electric energy compensated by the discharged electric energy Wd with the first system electric energy Ws1 is the discharged electric energy Wd, the discharge efficiency ηd, the discharge supply rate ηm, the power purchase It is calculated by multiplying the price Cp. In addition, in the relational expression, the electricity rate in the case of supplementing the power amount compensated by the discharge power amount Wd with the first system power amount Ws1 is described as F2. Also, the power purchase price Cp when the battery 31 is discharged is described as Cp2.

F2=Wd2×Cp2
= Wd x ηd x ηm x Cp2 (4-4)

Then, when the electricity bill for charging the electric energy for the discharged electric energy Wd is higher than the electricity bill when the electric energy compensated by the discharged electric energy Wd is supplemented by the system electric energy Ws, F1 is higher than F2. This is the case when it becomes expensive. Therefore, in this case, the following relational expression (4-5) holds using the above relational expressions (4-3) and (4-4). That is, in this case, the value obtained by multiplying the system supply rate ηs, the first charging efficiency ηc1, the discharge efficiency ηd, and the discharge supply rate ηm is the power purchase price Cp when the battery 31 is charged, and the value when the battery 31 is discharged. It is less than the value divided by the power purchase price Cp.

Further, if the electricity bill for charging the electric energy for the discharged electric energy Wd is equal to or less than the electricity bill when the electric energy compensated by the discharged electric energy Wd is supplemented by the system electric energy Ws, the user of the house 20 Save money on electricity bills. In this case, since F1 is less than or equal to F2, the following relational expression (4-6) holds. That is, in this case, the value obtained by multiplying the system supply rate ηs, the first charging efficiency ηc1, the discharge efficiency ηd, and the discharge supply rate ηm is the power purchase price Cp when the battery 31 is charged, and the value when the battery 31 is discharged. It is equal to or greater than the value divided by the power purchase price Cp.

F2 < F1
ηs×ηc1×ηd×ηm<Cp1/Cp2 (4-5)
F2≧F1
ηs×ηc1×ηd×ηm≧Cp1/Cp2 (4-6)

For example, the power purchase price Cp when charging the battery 31, that is, Cp1, is assumed to be 10 yen per unit power amount. The power purchase price Cp when the battery 31 is discharged, that is, Cp2 is assumed to be 20 yen per unit power amount. In this case, when the value obtained by multiplying the system supply rate ηs, the first charging efficiency ηc1, the discharge efficiency ηd and the discharge supply rate ηm is less than 50%, the user of the house 20 loses the electricity bill. Also, when the value obtained by multiplying the system supply rate ηs, the first charging efficiency ηc1, the discharge efficiency ηd, and the discharge supply rate ηm is 50% or more, the user of the house 20 will benefit from the electricity bill.

Then, based on the system supply rate ηs, the first charge efficiency ηc1, the discharge efficiency ηd, the discharge supply rate ηm, and the power purchase price Cp, the power control device 50 creates the charge/discharge plan Pcd in step S105. can determine the profit and loss of the electricity bill.

Here, as shown in FIG. 7, the power control device 50 controls the above-mentioned Since Cp2 is small, the value obtained by dividing Cp1 by Cp2 is large. In addition, as the power shortage Wi for each predetermined period decreases, the discharge power amount Wd and the first discharge supply amount Wd1 for each predetermined period decrease.

Further, here, as shown in FIG. 2, the discharge efficiency ηd decreases as the amount of power corresponding to the discharge efficiency ηd, that is, the amount of discharge power Wd decreases. Further, as the amount of electric power corresponding to the discharge supply rate ηm, that is, the first discharge supply amount Wd1 decreases, the discharge supply rate ηm decreases.

Further, during the time period from 17:00 to 21:00, in which the power purchase price Cp is relatively low and the power shortage Wi for each predetermined period is relatively large, the discharge power amount Wd and the first discharge supply amount Wd1 are large. Therefore, in the time period from 17:00 to 21:00, the discharge efficiency ηd and the discharge supply rate ηm are lower than in the time period from 21:00 to 24:00 in which the electric power shortage Wi for each predetermined period is relatively small. get higher Therefore, from 17:00 to 21:00, the above relational expression (4-6) holds true, so the user of the house 20 can save on the electricity bill. Therefore, in step S105, the power control device 50 creates a charging/discharging plan Pcd for discharging the battery 31 from 17:00 to 21:00.

Further, during the time period from 21:00 to 24:00 when the power purchase price Cp is relatively low and the power shortage Wi for each predetermined period is relatively small, the discharge power Wd and the first discharge supply Wd1 are small. Therefore, in the time period from 21:00 to 24:00, the discharge efficiency ηd and the discharge supply rate ηm are lower than in the time period from 17:00 to 21:00 in which the electric power shortage Wi for each predetermined period is relatively large. lower. Therefore, from 21:00 to 24:00, the above relational expression (4-5) holds true, so the user of the house 20 loses the electricity bill. Therefore, in step S105, the power control device 50 creates a charging/discharging plan Pcd that prohibits discharging of the battery 31 from 21:00 to 24:00. As a result, an increase in electricity bills is further suppressed.

In addition, the power control device 50 of the present embodiment also has the effects described below.

The power control device 50 calculates the system supply rate ηs, power generation supply rate ηg, first charging efficiency ηc1, second charging efficiency ηc2, discharge Calculate the actual power efficiency of the efficiency ηd and the discharge supply rate ηm. Then, based on these calculated values, the power control device 50 determines the system supply rate ηs, the power generation supply rate ηg, the first charging efficiency ηc1, the second charging efficiency ηc2, and the discharging efficiency when creating the charging/discharging plan Pcd. ηd and discharge supply rate ηm are corrected.

This improves the accuracy of the system supply rate ηs, the first charging efficiency ηc1, the discharge efficiency ηd, and the discharge supply rate ηm when creating the charge/discharge plan Pcd. Therefore, the accuracy of the third system power amount Ws3, the charge power amount Wc, and the first discharge supply amount Wd1 is improved, so that the accuracy of the system power amount Ws is improved. Therefore, the amount of deviation between the electricity bill during execution of the charging/discharging plan Pcd and the electricity bill when the charging/discharging plan Pcd is created is reduced, and an increase in the electricity bill is suppressed.

(Other embodiments)
The present invention is not limited to the above embodiments, and the above embodiments can be modified as appropriate. Further, in each of the above-described embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential, unless it is explicitly stated that they are essential, or they are clearly considered essential in principle. stomach.

Each predictor, generator, corrector, and technique described in this disclosure constitutes a processor and memory programmed to perform one or more functions embodied by a computer program. may be implemented by a dedicated computer provided by Alternatively, each predictor, generator, corrector and technique described in this disclosure may be implemented by a dedicated computer provided by configuring a processor with one or more dedicated hardware logic circuits. good. Alternatively, the predictors, generators, correctors and techniques described in this disclosure may be implemented using a processor and memory and one or more hardware logic circuits programmed to perform one or more functions. may be implemented by one or more dedicated computers configured in combination with a processor configured by The computer program may also be stored as computer-executable instructions on a computer-readable non-transitional tangible recording medium.

(1) In the above embodiment, the power control device 50 creates an efficiency map Me, which is the relationship between each power amount and each power efficiency. On the other hand, the power control device 50 creates an efficiency map Me of the first charging efficiency ηc1, the second charging efficiency ηc2, and the discharging efficiency ηd based on each electric energy and the battery temperature Tb of the battery 31 of the electric vehicle 30. may be created.

For example, when the battery 31 is charged and discharged when the battery temperature Tb is relatively low, it becomes difficult for ions that contribute to the charging and discharging of the battery 31 to move. When ions that contribute to charging and discharging of the battery 31 become difficult to move, the main reaction that contributes to charging and discharging of the battery 31 becomes difficult to proceed.
Also, when the battery 31 is charged and discharged when the battery temperature Tb is relatively high, substances generated by side reactions that do not contribute to the charging and discharging of the battery 31 tend to accumulate in the battery 31, and ions that contribute to the charging and discharging of the battery 31 becomes difficult to move. When ions that contribute to charging and discharging of the battery 31 become difficult to move, the main reaction that contributes to charging and discharging of the battery 31 becomes difficult to proceed. Therefore, as shown in FIG. 9, in the efficiency map Me when each power amount is a fixed value, when the battery temperature Tb is relatively low and when the battery temperature Tb is relatively high, the first charging efficiency ηc1, The second charging efficiency ηc2 and the discharging efficiency ηd are lowered.

In this case, in step S101, power control device 50 acquires vehicle identification number ID and battery temperature Tb as vehicle information via battery control unit 33, charge/discharge cable 41, and charge/discharge control unit 44. Power control device 50 then reads efficiency map Me corresponding to vehicle identification number ID and battery temperature Tb.

Further, in step S110, power control device 50 corresponding to the temperature reading unit and temperature correcting unit acquires each amount of power and battery temperature Tb when battery 31 is being charged/discharged according to charging/discharging plan Pcd.

Also, in step S111, power control device 50 plots the corresponding electric energy and battery temperature Tb and charging efficiency ηc and discharging efficiency ηd calculated in step S110. Then, the power control device 50 corrects the efficiency map Me using the plotted values. For example, when each power amount is a fixed value, the power control device 50 adds each plot point for the currently calculated temperature to each plot point for the temperature calculated and accumulated in the past, and reproduces each function. form. In the initial state, the relationship between battery temperature Tb and charging efficiency ηc and discharging efficiency ηd is set in advance. These initial values are set through experiments and simulations.

Accuracy of the first charging efficiency ηc1, the second charging efficiency ηc2, and the discharging efficiency ηd when the charging/discharging plan Pcd is created by the power control device 50 creating the efficiency map Me based on the electric energy and the battery temperature Tb. is further improved. Thereby, the power control device 50 has the same effects as described above.

(2) In the above embodiment, the initial values of the efficiency map Me created by the power control device 50 are set in advance through experiments and simulations. On the other hand, when the power control device 50 does not store the efficiency map Me in the initial state, the power control device 50 stores the efficiency map Me when the battery 31 of the electric vehicle 30 arranged in each of the plurality of houses 20 is charged and discharged. You may acquire from the information server 60 which accumulates.

In this case, in step S<b>101 , the charge/discharge control unit 44 acquires the vehicle type of the electric vehicle 30 as vehicle information from the battery control unit 33 via the charge/discharge cable 41 . Further, the power control device 50 acquires the vehicle type of the electric vehicle 30 stored in the charge/discharge control unit 44 and acquires the efficiency map Me corresponding to the acquired vehicle type from the information server 60 . Then, in loop L1, power control device 50 uses efficiency map Me obtained from information server 60 to create charge/discharge plan Pcd.

(4) In the above embodiment, the power control device 50 creates the charge/discharge plan Pcd for charging/discharging the battery 31 . On the other hand, the power control device 50 may create a charge/discharge plan Pcd for only charging the battery 31 . For example, in response to an operation by a user who wishes to charge only the battery 31, the power control device 50 creates a charge/discharge plan Pcd for only charging the battery 31, as shown in FIG.

(4) In the above embodiment, the power control device 50 creates the charge/discharge plan Pcd for charging/discharging the battery 31 . On the other hand, the power control device 50 may create a charge/discharge plan Pcd that only discharges the battery 31 . For example, when the battery 31 is fully charged and the user wishes to only discharge the battery 31, the power control device 50, as shown in FIG. to create

(5) In the above embodiment, the power control device 50 executes the charging/discharging plan Pcd selected in step S108. On the other hand, during execution of the charge/discharge plan Pcd, the power control device 50 calculates the system supply rate ηs, the power generation supply rate ηg, the first charge efficiency ηc1, the second charge efficiency ηc2, the discharge efficiency ηd, and the discharge supply rate. You may change the execution content of the charge/discharge plan Pcd based on (eta)m. For example, the electric power control device 50 is configured such that the system supply rate ηs, power generation supply rate ηg, first charging efficiency ηc1, second charging efficiency ηc2, discharge efficiency ηd, and discharge supply rate ηm during execution are low and the electricity rate is high. is expected, the charging and discharging of the battery 31 is stopped.

(6) In the above embodiment, the power control device 50 regards the power loss due to the distribution board 23 as zero. On the other hand, the power control device 50 may not regard the power loss due to the distribution board 23 as zero, and may add it to the calculation of the electricity rate and the like.

(summary)
According to the first aspect, the power control device creates a battery charging/discharging plan based on power generation prediction data, consumption prediction data, grid supply rate, and charging efficiency. This allows the power control device to create a charging/discharging plan for charging the battery when the grid supply rate and charging efficiency are high. By allowing the battery to charge when the grid availability and charging efficiency are high, less grid power is used to charge the battery than when the grid availability and charging efficiency are low. Therefore, the power control device can reduce the electricity bill and suppress an increase in the electricity bill.

According to the second aspect, the power control device creates a charge/discharge plan for charging the battery with a charging power amount that maximizes the system supply rate and charging efficiency. As a result, the power control device can reduce the electricity bill and suppress an increase in the electricity bill.

According to the third aspect, the power control device corrects the charging efficiency when creating the charging/discharging plan based on the charging efficiency when the battery is charged. This improves the accuracy of the charging efficiency, thereby improving the accuracy of the system power amount used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

According to the fourth aspect, the power control device corrects the system supply rate when creating the charge/discharge plan based on the system supply rate when the battery is charged. This improves the accuracy of the grid power supply rate, thereby improving the accuracy of the grid power amount used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

According to the fifth aspect, the power control device corrects the relationship between the temperature of the battery and the charging efficiency when creating the charging/discharging plan based on the temperature of the battery when the battery is charged. This improves the accuracy of the charging efficiency, thereby improving the accuracy of the system power amount used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

According to the sixth aspect, the power control device creates a battery charging/discharging plan based on power generation prediction data, consumption prediction data, discharge efficiency, and discharge supply rate. This allows the power control device to create a charge/discharge plan that prohibits battery discharge when the discharge efficiency and discharge supply rate are low. By inhibiting the discharge of the battery when the discharge efficiency and the discharge supply rate are low, an increase in the discharge power amount used to make up for the power shortage is suppressed. If the discharge power amount used to make up for the power shortage is suppressed from increasing, the system power amount used to charge the battery is suppressed from increasing. Therefore, the power control device can suppress an increase in electricity bills.

According to the seventh aspect, the power control device creates a charge/discharge plan that prohibits battery discharge based on the discharge efficiency and the discharge supply rate. Thereby, the power control device can suppress an increase in the electricity bill.

According to the eighth aspect, the power control device determines that the product of the system supply rate, the charging efficiency, the discharging efficiency, and the discharging supply rate is the power purchase price when charging the battery, and the power purchase price when discharging the battery. Create a charge/discharge schedule that prohibits discharging the battery when it is less than the value divided by . Thereby, the power control device can suppress an increase in the electricity bill.

According to the ninth aspect, the power control device corrects the discharge efficiency when creating the charge/discharge plan based on the discharge efficiency when the battery is discharged. This improves the accuracy of the discharge efficiency, thereby improving the accuracy of the system power amount Ws used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

According to the tenth aspect, the power control device corrects the discharge supply rate when creating the charge/discharge plan based on the discharge supply rate when the battery is discharged. This improves the accuracy of the discharge supply rate, thereby improving the accuracy of the system power amount used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

According to the eleventh aspect, the power control device corrects the discharge efficiency when creating the charge/discharge plan based on the temperature of the battery when the battery is discharged. This improves the accuracy of the discharge efficiency, thereby improving the accuracy of the system power amount used. Therefore, the amount of deviation between the electricity bill during execution of the charge/discharge plan and the electricity bill when the charge/discharge plan is created is reduced, and an increase in the electricity bill is suppressed.

20 building 21 power generator 24 power consumption device 30 power storage device 31 battery 40 power storage device 50 power control device

Claims (9)

a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
The power generation forecast data, the consumption forecast data, and the power amount (Ws2) supplied from the system power source (11) to the charge/discharge device (40) that charges and discharges the battery (31) of the power storage device (30). A system supply rate (ηs) that is a ratio of the amount of power (Ws3) supplied to the battery from the discharging device and the power charged to the battery with respect to the amount of power (Ws3) supplied to the storage device from the charging/discharging device a plan creation unit (S105) that creates a charge/discharge plan (Pcd) for the battery based on the charging efficiency (ηc1) that is the ratio of the amount (Wc);
Based on the ratio (ηc1) of the electric energy (Wc) charged in the battery to the electric energy (Ws3) supplied from the charging/discharging device to the power storage device when the battery is charged, the plan creation unit A charging correction unit (S111) that corrects the charging efficiency when creating the charging and discharging plan;
A power control device comprising: a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
The power generation forecast data, the consumption forecast data, and the power amount (Ws2) supplied from the system power source (11) to the charge/discharge device (40) that charges and discharges the battery (31) of the power storage device (30). A system supply rate (ηs) that is a ratio of the amount of power (Ws3) supplied to the battery from the discharging device and the power charged to the battery with respect to the amount of power (Ws3) supplied to the storage device from the charging/discharging device a plan creation unit (S105) that creates a charge/discharge plan (Pcd) for the battery based on the charging efficiency (ηc1) that is the ratio of the amount (Wc);
Based on the ratio (ηs) of the amount of power (Ws3) supplied to the battery from the charging/discharging device to the amount of power (Ws2) supplied to the charging/discharging device from the system power source when the battery is charged a supply correction unit (S111) for correcting the system supply rate when the plan creation unit creates the charge/discharge plan;
A power control device comprising: a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
The power generation forecast data, the consumption forecast data, and the power amount (Ws2) supplied from the system power source (11) to the charge/discharge device (40) that charges and discharges the battery (31) of the power storage device (30). A system supply rate (ηs) that is a ratio of the amount of power (Ws3) supplied to the battery from the discharging device and the power charged to the battery with respect to the amount of power (Ws3) supplied to the storage device from the charging/discharging device a plan creation unit (S105) that creates a charge/discharge plan (Pcd) for the battery based on the charging efficiency (ηc1) that is the ratio of the amount (Wc);
a temperature reading unit (S101) that reads the charging efficiency based on the temperature (Tb) of the battery;
power amount (Ws3) supplied from the charge/discharge device to the power storage device corresponding to the temperature of the battery acquired when the battery is charged and the temperature of the battery acquired when the battery is charged a temperature correction unit (S111) that corrects the relationship between the temperature of the battery and the charging efficiency based on the ratio (ηc1) of the electric energy (Wc) charged in the battery;
A power control device comprising: 2. The plan creation unit creates the charge/discharge plan (Pcd) for charging the battery with an amount of electric power (Wc) charged to the battery that maximizes the system supply rate and the charging efficiency. 4. The power control device according to any one of 1 to 3 . a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
Electric power supplied from the battery to the electric energy (Wd) discharged by the battery (31) of the power storage device (30) to the charging/discharging device (40) for charging and discharging the battery (40), based on the power generation prediction data, the consumption prediction data, and the amount of electric power (Wd) discharged by the battery (31) of the power storage device (30). discharge efficiency (ηd), which is a ratio of the amount (Wd1), and the ratio of the amount of power (Wd2) supplied from the charge/discharge device to the power consumption device with respect to the amount of power (Wd1) supplied from the battery to the charge/discharge device a plan creation unit (S105) that creates a charge/discharge plan for the battery based on a discharge supply rate (ηm) that is a ratio;
When the battery is discharged, based on the ratio (ηd) of the amount of power (Wd1) supplied from the battery to the charging/discharging device with respect to the amount of power (Wd) discharged by the battery, the plan creation unit A discharge correction unit (S111) that corrects the discharge efficiency when creating a charge/discharge plan;
A power control device comprising: a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
Electric power supplied from the battery to the electric energy (Wd) discharged by the battery (31) of the power storage device (30) to the charging/discharging device (40) for charging and discharging the battery (40), based on the power generation prediction data, the consumption prediction data, and the amount of electric power (Wd) discharged by the battery (31) of the power storage device (30). discharge efficiency (ηd), which is a ratio of the amount (Wd1), and the ratio of the amount of power (Wd2) supplied from the charge/discharge device to the power consumption device with respect to the amount of power (Wd1) supplied from the battery to the charge/discharge device a plan creation unit (S105) that creates a charge/discharge plan for the battery based on a discharge supply rate (ηm) that is a ratio;
Based on the ratio (ηm) of the amount of power (Wd2) supplied from the charging/discharging device to the power consuming device with respect to the amount of power (Wd1) supplied from the battery to the charging/discharging device when the battery is discharged a supply correction unit (S111) for correcting the discharge supply rate when the plan creation unit creates the charge/discharge plan;
A power control device comprising: a power generation prediction unit (S102) that creates power generation prediction data (Dgf) that is a prediction of the transition of the amount of power generated by the power generation device (21) installed in the building (20);
a consumption prediction unit (S103) that creates consumption prediction data (Dcf) that is a prediction of changes in the amount of power consumed by the power consumption equipment (24) installed in the building;
Electric power supplied from the battery to the electric energy (Wd) discharged by the battery (31) of the power storage device (30) to the charging/discharging device (40) for charging and discharging the battery (40), based on the power generation prediction data, the consumption prediction data, and the amount of electric power (Wd) discharged by the battery (31) of the power storage device (30). discharge efficiency (ηd), which is a ratio of the amount (Wd1), and the ratio of the amount of power (Wd2) supplied from the charge/discharge device to the power consumption device with respect to the amount of power (Wd1) supplied from the battery to the charge/discharge device a plan creation unit (S105) that creates a charge/discharge plan for the battery based on a discharge supply rate (ηm) that is a ratio;
a temperature reading unit (S101) that reads the discharge efficiency based on the temperature (Tb) of the battery;
The charging/discharging device from the battery with respect to the temperature of the battery obtained when the battery is discharged and the amount of electric power (Wd) discharged by the battery corresponding to the temperature of the battery obtained when the battery is discharged a temperature correction unit (S111) that corrects the relationship between the temperature of the battery and the discharge efficiency based on the ratio (ηd) of the electric energy (Wd1) supplied to the
A power control device comprising: The power control device according to any one of claims 5 to 7, wherein the plan creation unit creates the charge/discharge plan for prohibiting discharge of the battery based on the discharge efficiency and the discharge supply rate. The plan creation unit calculates the ratio (ηs) of the amount of power (Ws3) supplied to the battery from the charging/discharging device to the amount of power (Ws2) supplied to the charging/discharging device from the system power source (11), the The ratio (ηc1) of the electric energy (Wc) charged in the battery to the electric energy (Ws3) supplied from the charging/discharging device to the power storage device, the product of the discharge efficiency and the discharge supply rate is the charging power of the battery. 8. creating the charging/discharging plan for prohibiting the discharging of the battery when the power purchase price (Cp1) when the battery is discharged is less than a value obtained by dividing the power purchase price (Cp1) when the battery is discharged by the power purchase price (Cp2) when the battery is discharged; The power control device according to .

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