JP2018196231A - Power controller - Google Patents

Abstract

To obtain a power controller for controlling charge and discharge of a storage battery while suppressing deterioration of the storage battery.SOLUTION: A power controller 1 includes: a DC voltage conversion circuit 12 for converting a voltage of DC power obtained by a solar module 4 to a constant voltage; a storage battery charge/discharge circuit 13 for making a storage battery 5 store the DC power; and a control unit 15. The storage battery charge/discharge circuit 13 has a function for making the storage battery 5 discharge power. The control unit 15 performs control of allocating power discharged from the storage battery 5 to power to be consumed by a load 7 that operates using power. The control unit 15, on the basis of data on weather forecasting, determines whether or not photovoltaic power generation is performed on a control target day; and performs control of reducing an amount of power to be stored in the storage battery 5, on the basis of a determination result and the load 7's amount of power consumption for each time zone identified on the basis of load data showing power consumption of the load 7 and utilization time data showing a time in which the load 7 is used for each time zone.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a power control device that controls charging and discharging of a storage battery.

  A conventional power control device receives power from a power company through a power system and stores it in a storage battery at midnight, and stores it in a storage battery in the morning hours and daytime hours. Electric power discharged from the storage battery by discharging the storage battery during a part or all of the time zone and night time zone is output to the load. Alternatively, the conventional power control device allows the storage battery to store the power obtained by solar power generation during the daytime period, and a part or all of the morning time period, the night time period, and the midnight time period. The electric power discharged from the storage battery by being discharged to the storage battery is output to the load.

  The price of power supplied from the power company in the midnight time zone is lower than the price of power supplied from the power company in the morning time zone, noon time zone, and night time zone. The price of the electric power obtained by the photovoltaic power generation is free except for the price of the solar module and the price for work when installing the solar module. In other words, the conventional power control device causes the storage battery to store relatively inexpensive power or free power, and discharges the storage battery from the storage battery in a time zone when the price of power supplied from the power company is relatively high. The discharged power is output to the load. In the conventional power control device, the time zone for charging and discharging the storage battery and the remaining amount of power stored in the storage battery are set by the user. A conventional power control apparatus controls charging and discharging of a storage battery according to set items.

  Conventionally, there has also been proposed a power control apparatus that divides the capacity of a storage battery into a plurality of quantities and manages charge and discharge for each of the divided quantities (see, for example, Patent Document 1).

International Publication No. 2015/011746

  However, the conventional power control device does not cause the storage battery to discharge relatively when the storage battery stores a relatively large amount of power and can receive relatively inexpensive power or free power. Allocate low-price power or free power to the power consumed by the load. That is, conventionally, a state in which a relatively large amount of power is stored in the storage battery may continue for a relatively long time. If a state in which a relatively large amount of power is stored in the storage battery lasts for a relatively long time, the storage battery is likely to deteriorate as compared to a case in which a relatively small amount of power is stored in the storage battery for a relatively long time.

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the electric power control apparatus which controls charge and discharge of a storage battery by suppressing deterioration of a storage battery.

  In order to solve the above-described problems and achieve the object, the present invention is a power control apparatus that controls charging and discharging of a storage battery, and includes a solar panel that includes a solar panel that generates power based on sunlight. A DC voltage conversion circuit that converts the voltage of the obtained DC power into a constant voltage, a storage battery charging / discharging circuit that stores the DC power obtained by the DC voltage conversion circuit in the storage battery, and AC power from the power system A direct current alternating current conversion circuit for converting into direct current power, data on weather forecast data for a target of charge and discharge control of the storage battery, load data indicating power consumption of a load that operates using electric power, and the control A storage unit that stores usage time data indicating a time during which the load is used for each time zone on the target day, the weather forecast data stored in the storage unit, the load data, and Based on the serial usage time data, and a control section for controlling the DC voltage converter, the battery charging discharge circuit and the DC-AC converter. The storage battery charging / discharging circuit has a function of discharging the storage battery. The control unit performs control for allocating the power discharged from the storage battery to the power consumed by the load, and whether or not solar power generation is performed on the control target day based on the weather forecast data. The amount of power stored in the storage battery is reduced based on the determination result and the power consumption for each load time zone specified based on the load data and the usage time data. Control.

  The present invention has an effect that it is possible to control charging and discharging of a storage battery while suppressing deterioration of the storage battery.

The figure which shows the condition where the power control apparatus concerning embodiment was installed in the house The figure which shows the structure of the electric power control apparatus concerning embodiment Figure showing four time zones when one day is divided into four time zones The figure which shows each information of the some load concerning embodiment The figure which shows the information for demonstrating operation | movement of the power control apparatus concerning embodiment The flowchart which shows a part of procedure of an example of operation | movement of the power control apparatus concerning embodiment. The flowchart which shows the remainder of the procedure of an example of operation | movement of the power control apparatus concerning embodiment The figure which shows the example of transition of the capacity | capacitance of the electric power stored in a storage battery by control by the electric power control apparatus concerning embodiment A diagram showing an example of changes in power consumption during summer weekdays and holidays The figure which shows an example of transition of power consumption of weekdays and holidays on spring and autumn The figure which shows an example of transition of the capacity | capacitance of the electric power currently stored in the storage battery of the past and embodiment on a summer weekday The figure which shows an example of transition of the capacity | capacitance of the electric power currently stored in the storage battery of the past and embodiment on a summer holiday The figure which shows an example of transition of the capacity | capacitance of the electric power currently stored in the storage battery of the past and embodiment on the weekday of spring and autumn The figure which shows an example of transition of the capacity | capacitance of the electric power currently stored in the storage battery of the past and embodiment on the holiday of spring and autumn The figure which shows the life characteristic of the storage battery which shows the relationship between the ratio of the remaining amount of a storage battery, and the deterioration ratio of a storage battery The figure which shows a processing circuit in case the at least one component which comprises the control part which the power control apparatus concerning embodiment has is implement | achieved by a processing circuit The figure which shows a processor in case the at least one part function of the control part which the power control apparatus concerning embodiment has is implement | achieved by a processor

  Hereinafter, a power control apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
FIG. 1 is a diagram illustrating a state in which the power control apparatus 1 according to the embodiment is installed in a house 2. The house 2 further includes a solar module 4 having a plurality of solar panels 3 that generate power based on sunlight, and a storage battery 5. The solar module 4 may have only one solar panel 3. The power control device 1 is connected to the solar module 4 and the storage battery 5. The power control device 1 is also connected to the power system 6. In the house 2, a load 7 that operates using electric power is used.

  The electric power control apparatus 1 can receive the electric power obtained by the solar panel 3 generating electric power based on sunlight from the solar module 4, and the electric power supplied to the house 2 from the electric power company 6 can be received. Further, the power control apparatus 1 can store the received power in the storage battery 5 and can supply the received power to the load 7. Furthermore, the power control device 1 can supply the load 7 with the power discharged from the storage battery 5 by discharging the storage battery 5.

  That is, the power control device 1 is a device that controls charging and discharging of the storage battery 5. An example of the load 7 is a cooling device or a heating device. An operation terminal device 8 that can be operated by a resident of the house 2 is further installed in the house 2. The operation terminal device 8 is connected to the power control device 1 and the Internet 9.

  FIG. 2 is a diagram illustrating a configuration of the power control apparatus 1 according to the embodiment. The power control apparatus 1 includes a power conversion circuit 11 that can perform conversion from DC power to AC power and conversion from AC power to DC power. The power conversion circuit 11 is connected to a solar module 4 having a solar panel 3 that generates power based on sunlight. FIG. 2 also shows a solar module 4 that obtains DC power based on sunlight.

  The voltage of the DC power obtained by the solar module 4 varies depending on the weather conditions. The power conversion circuit 11 has a DC voltage conversion circuit 12 that converts the voltage of the DC power obtained by the solar module 4 into a constant voltage. An example of the constant voltage is 100V or 200V. The power conversion circuit 11 is also connected to the storage battery 5. The storage battery 5 is also shown in FIG.

  The power conversion circuit 11 further includes a storage battery charging / discharging circuit 13 that stores the DC power obtained by the DC voltage conversion circuit 12 in the storage battery 5. The DC voltage conversion circuit 12 has a function of outputting DC power of the above-described constant voltage to the storage battery charging / discharging circuit 13. When the DC voltage conversion circuit 12 outputs DC power to the storage battery charging / discharging circuit 13, the storage battery charging / discharging circuit 13 converts the DC power from the DC voltage conversion circuit 12 into DC power of a voltage suitable for the storage battery 5 to store the storage battery 5. To store. The storage battery charging / discharging circuit 13 also has a function of causing the storage battery 5 to discharge.

  The power conversion circuit 11 is also connected to the power system 6 and the load 7. FIG. 2 also shows the power system 6 and the load 7. As described above, an example of the load 7 is a cooling device or a heating device. A specific example of the load 7 will be described later. The power conversion circuit 11 further includes a DC / AC conversion circuit 14 that converts the DC power obtained by the DC voltage conversion circuit 12 into AC power.

  The DC voltage conversion circuit 12 has a function of outputting DC power of the above-described constant voltage to the DC / AC conversion circuit 14. When the DC voltage conversion circuit 12 outputs DC power to the DC / AC conversion circuit 14, the DC / AC conversion circuit 14 converts the DC power from the DC voltage conversion circuit 12 into AC power, and the obtained AC power is converted into a power system. 6 or load 7 is output. The output of AC power to the power system 6 by the DC / AC conversion circuit 14 corresponds to power sale.

  As described above, the storage battery charging / discharging circuit 13 also has a function of causing the storage battery 5 to discharge, and the DC power discharged from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. When the DC / AC conversion circuit 14 receives DC power from the storage battery 5 via the storage battery charging / discharging circuit 13, the DC / AC conversion circuit 14 converts the received DC power into AC power having a voltage corresponding to the load 7, and the obtained AC power is converted. Output to load 7.

  The DC / AC conversion circuit 14 also has a function of receiving AC power from the power system 6, converting the voltage of the received AC power into a voltage corresponding to the load 7, and outputting the obtained AC power to the load 7. When the AC power is output to the load 7, the DC / AC conversion circuit 14 outputs 100 V or 200 V AC power, which is a household AC voltage, to the load 7. That is, the voltage corresponding to the load 7 is 100V or 200V.

  The DC / AC conversion circuit 14 also has a function of receiving AC power from the power system 6, converting the received AC power into DC power, and outputting the DC power to the storage battery charging / discharging circuit 13. When the DC / AC conversion circuit 14 outputs DC power to the storage battery charging / discharging circuit 13, the storage battery charging / discharging circuit 13 converts the DC power from the DC / AC conversion circuit 14 into DC power having a voltage suitable for the storage battery 5 to store the storage battery 5. To store.

  The power control apparatus 1 further includes a control unit 15 that controls the power conversion circuit 11. Specifically, the control unit 15 controls operations of the DC voltage conversion circuit 12, the storage battery charging / discharging circuit 13, and the DC / AC conversion circuit 14 included in the power conversion circuit 11. In addition, the control unit 15 manages the internal temperature of the power conversion circuit 11. Further, the control unit 15 protects the DC voltage conversion circuit 12, the storage battery charging / discharging circuit 13, and the DC AC conversion circuit 14 when an abnormality occurs in the power conversion circuit 11.

  The power control apparatus 1 further includes a storage unit 16 that stores load data 21 indicating the power consumption of the load 7. An example of the storage unit 16 is a flash memory. The storage unit 16 further stores season data 22 indicating the season in which the load 7 is used and the change in the power consumption of the load 7 for each season. The storage unit 16 further stores use day time data 23 indicating what day of the week the load 7 is used. The day-of-use time data 23 includes usage time data indicating the time during which the load 7 is used for each time zone on the target day of charge and discharge control of the storage battery 5 by the power control device 1. When a plurality of people live in the house 2 where the power control device 1 is disposed and a plurality of loads 7 are used in the house 2, the storage unit 16 uses which load 7 at which place which user uses. The user data 24 indicating whether or not is stored. The user is a resident of the house 2.

  The memory | storage part 16 further memorize | stores the weather data 25 which shows the information of the weather of the area where the house 2 exists. The weather data 25 includes weather forecast data for the day to be controlled for charging and discharging of the storage battery 5, and is used for estimating the amount of power generated by the solar module 4 on the day to be controlled. The control unit 15 manages a storage unit 16 that stores load data 21, season data 22, use day / time data 23, user data 24, and weather data 25.

  The storage unit 16 is connected to an operation terminal device 8 that can be operated by a user. FIG. 2 also shows the operation terminal device 8. For example, some or all of the load data 21, season data 22, use day / time data 23, user data 24, and weather data 25 are input to the storage unit 16 when the user operates the operation terminal device 8. It is stored in the storage unit 16.

  The operation terminal device 8 is connected to the Internet 9. FIG. 2 also shows the Internet 9. The operation terminal device 8 receives part or all of the load data 21, season data 22, use day / time data 23, user data 24, and weather data 25 from the Internet 9, and the data received by the operation terminal device 8 is stored. It may be stored in the unit 16. That is, the data stored in the storage unit 16 may be data obtained from the Internet 9. The user can update the data stored in the storage unit 16 by using the Internet 9 and the operation terminal device 8.

  A sensor 17 that measures one or both of the amount of sunlight and the temperature outside the power control device 1 is attached to the outside of the casing of the power control device 1, and information obtained by the sensor 17 is stored in the storage unit 16. It may be inputted and stored in the storage unit 16. The outside of the power control device 1 is the outside of the house 2 where the power control device 1 is installed. Information obtained by the sensor 17 may be part of the weather data 25. Based on at least weather forecast data and load data 21 stored in the storage unit 16, the control unit 15 includes a DC voltage conversion circuit 12, a storage battery charge / discharge circuit 13, and a DC AC conversion circuit 14 included in the power conversion circuit 11. Control. The function of the control unit 15 will be described later when the operation of the power control device 1 is described.

  The house 2 in which the power control apparatus 1 is installed is supplied with electric power from the electric power company through the electric power system 6, and the resident of the house 2 purchases electric power from the electric power company at a price based on a contract with the electric power company. The price of electricity varies depending on the time of day. Specifically, the price in the time zone where the demand for power is relatively low is relatively low, and the price in the time zone where the demand for power is relatively high is relatively high. An example of a time zone in which the demand for power is relatively low is a midnight time zone. An example of a time zone where demand for power is relatively high is a daytime time zone.

  The power control device 1 receives power from the power company via the power system 6 by purchasing power in a time zone where the price is relatively low according to the required power amount based on preset information, and receives the received power Can be stored in the storage battery 5. The information set in advance is information stored in the storage unit 16. The required power amount is the power consumption amount of the load 7.

  A solar module 4 having a solar panel 3 that generates electric power based on sunlight is installed in a house 2 in which the power control device 1 is installed. The power control device 1 can also store the power obtained by the solar module 4 by solar power generation in the storage battery 5. In other words, the power control device 1 can cause the storage battery 5 to store the power obtained by the solar panel 3 generating power based on sunlight. The electric power obtained by the solar power generation is free except for the price of the solar module 4 and the price for the work when installing the solar module 4 in the house 2. That is, the price of power obtained by solar power generation is lower than the price of power supplied from the power company via the power system 6.

  An example of the load 7 used in the house 2 is a cooling device, a heating device, a television set, a personal computer, a cooking appliance, a lighting device, a water heater, a tool, an elevator, a telephone, an intercom, a communication device, a refrigerator, a hot water toilet seat, It is a vacuum cleaner, washing machine, radio, electric fan or ventilation device. A person who uses the load 7 lives in the house 2. In the house 2, a plurality of loads 7 are used. In the embodiment, it is assumed that a plurality of people live in the house 2. For example, the plurality of persons are a father, a mother, and a child that constitute one family.

  When a plurality of loads 7 are used in the house 2 and a plurality of people live in the house 2, the specific load 7 may be used only by a specific person. A person who uses the load 7 is a user. Among the plurality of loads 7, there are those in which the seasons used are limited. An example of the load 7 in which the season used is limited is a cooling device. Some of the plurality of loads 7 are used only in a specific time zone. An example of the load 7 used only in a specific time zone is a cooking utensil.

  The power control device 1 manages a time zone in which the load 7 is used, a time zone in which the storage battery 5 is charged, and a time zone in which the storage battery 5 should be discharged. The user can set the time zone managed by the power control apparatus 1 in units of 1 minute, 30 minutes, or 1 hour, for example, but in the embodiment, one day has four times shown in FIG. Divided into bands. FIG. 3 is a diagram showing four time zones when one day is divided into four time zones.

  In other words, in the embodiment, one day is divided into four time zones, namely, a midnight time zone T1, a morning time zone T2, a daytime time zone T3, and a night time zone T4. The four time zones vary depending on the region, environment, season, user lifestyle, or power company handling. The four time zones in FIG. 3 are an example of a plurality of time zones when one day is divided into a plurality of time zones.

  The midnight time zone T1 is a time zone from 23:00 on the day before an arbitrary day to 6 am on the arbitrary day. The midnight time zone T1 is a midnight time zone for the electric power company. The price of power supplied from the power company to the house 2 during the midnight time zone T1 is lower than the price of power supplied from the power company to the house 2 during the day. In the late-night time period T1, there are relatively many people who go to bed and relatively little living activity. In the late-night time period T1, the use of household appliances is relatively small. An example of a household appliance is a cooking utensil.

  The power consumption amount of the load 7 in the midnight time zone T1 is defined as the power consumption amount P1, and the amount of power that can be stored in the storage battery 5 in the midnight time zone T1 is defined as the chargeable power amount C1. The chargeable power amount C1 varies depending on the contract power of the user of the house 2 and the power consumption amount P1. The chargeable power amount C1 is calculated by an expression “C1 = (contract power × time of midnight time zone T1) −P1)”. Or chargeable electric energy C1 is a rating of the capacity of storage battery 5. The contract power is specified by the amperage, for example.

  The morning time zone T2 is a time zone from 6 am on any given day to 10 am on any given day. The price of power supplied from the power company to the house 2 in the morning time zone T2 is a normal price. That is, the price of power supplied from the power company to the house 2 in the morning time zone T2 is higher than the price of power supplied from the power company to the house 2 in the midnight time zone T1. In the morning time zone T2, a relatively large number of users get up, and the users who get up use cooking utensils to prepare for breakfast. In the morning time zone T2, the solar panel 3 does not generate power because the sun is relatively low. The power consumption amount of the load 7 in the morning time zone T2 is defined as the power consumption amount P2. In the morning time zone T2, the storage battery 5 is not charged.

  The noon time zone T3 is a time zone from 10:00 am on any given day to 16:00 on any given day. The daytime time zone T3 is a time zone in which the solar panel 3 generates power based on sunlight. Since the electric power obtained by the solar panel 3 generating electricity based on sunlight is free, the daytime time zone T3 can charge the storage battery 5 at the lowest cost among the four time zones. It is a time zone. The amount of power consumed by the load 7 in the daytime time zone T3 is defined as the power consumption amount P3, and the amount of power that can be stored in the storage battery 5 in the daytime time zone T3 is defined as the chargeable power amount C3.

  It is assumed that the electric power from the electric power company is not supplied to the house 2 in the daytime period T3. In this case, the chargeable power amount C3 is calculated by an expression “C3 = amount of power obtained by the solar panel 3 generating power based on sunlight−P3”. The weekday noon time zone T3 is a time zone in which the user works or goes to school. When the arbitrary one day is a holiday, a cooking utensil is used, for example, for lunch in the daytime period T3.

  The night time zone T4 is a time zone from 16:00 of the arbitrary day to 23:00 of the arbitrary day. Since the night time zone T4 is a time zone after sunset, the solar panel 3 does not generate power in the night time zone T4. The night time zone T4 is a time zone in which the user returns from work or school to the house 2. That is, the night time zone T4 is a time zone when the user returns home. In the evening time zone T4, the cooking utensils are used for cooking dinner. In the time from the beginning of the night time zone T4 until the user goes to bed, things related to entertainment are performed. For example, a television set is used, and a water heater is used for bathing. The power consumption amount of the load 7 in the night time zone T4 is defined as the power consumption amount P4.

  Due to the influence of one or both of the season and the lifestyle of the user, the night time period T4 is not limited to the time period from 16:00 of the given day to 23:00 of the given day. . For example, in the winter when the daytime is relatively short, the night time zone T4 may be a time zone from 15:00 of any given day to 23:00 of any given day. In that case, the noon time zone T3 is a time zone from 10:00 am on any given day to 15:00 on any given day. When the time for the user to go home is relatively late, the night time period T4 may be a time period from 18:00 or 19:00 of any given day to 23:00 of any given day. . In that case, the noon time zone T3 is a time zone from 10:00 am of the arbitrary day to 18:00 or 19:00 of the arbitrary day.

  The power control apparatus 1 controls the charging and discharging of the storage battery 5 so that the power supplied to the load 7 is not insufficient and the cost for consumption of the power used by the load 7 is as low as possible. The electric power stored in the storage battery 5 is consumed in the load 7. Next, items for explaining the operation of the power control apparatus 1 will be described. FIG. 4 is a diagram illustrating information on each of the plurality of loads 7 according to the embodiment. The information shown in FIG. 4 is stored in the storage unit 16.

  As shown in FIG. 4, users of the load 7 are a father, a mother, and a child who live in the house 2. FIG. 4 shows eight loads 7. The first load 7 is a first cooling device, and the first cooling device is installed in a relatively large living room of the house 2. In FIG. 4, the first cooling device is described as “first cooling”. The second load 7 is a second cooling device, and the second cooling device is installed in a relatively small child room of the house 2. In FIG. 4, the second cooling device is described as “second cooling”.

  The third load 7 is a first heating device, and the first heating device is installed in the living room of the house 2. In FIG. 4, the first heating device is described as “first heating”. The fourth load 7 is a second heating device, and the second heating device is installed in the child room of the house 2. In FIG. 4, the second heating device is described as “second heating”.

  The fifth load 7 is a television set, and the sixth load 7 is a personal computer. In FIG. 4, the television set is described as “TV”, and the personal computer is described as “PC”. The character string “TV / PC” in FIG. 4 means a television set and a personal computer. The character string “TV / PC” is also used in FIG. 5 and FIG. The seventh load 7 is a cooking utensil, and the eighth load 7 is a lighting device. In FIG. 4, the cooking utensil is described as “cooking”, and the lighting device is described as “illumination”.

  FIG. 4 shows information for identifying the power consumption, the user, the time zone used on weekdays, the time zone used on holidays, and the season used for each of the plurality of loads 7. Yes. The unit of power consumption is kilowatt. In FIG. 4, kilowatt is described as “kW”. In FIG. 4, the time zone used on weekdays is described as “weekday time zone”, and the time zone used on holidays is described as “holiday time zone”. “KW”, “weekday time zone”, and “holiday time zone” are also used in FIG. 5 and FIG.

  In FIG. 4, “T1” means the midnight time zone T1, “T2” means the morning time zone T2, “T3” means the daytime time zone T3, and “T4” means the night time. This means the band T4. In FIG. 4, “23-6” means from 23:00 on the day before any given day to 6 am on any given day, and “6-10” represents the morning on any given day. It means from 6am to 10am on any given day. “10-16” means from 10:00 am on any given day to 16:00 on any given day, and “16-23” refers to any given date from 16:00 on any given day It means until 13:00 on one day. Each of the plurality of loads 7 is used depending on the item marked with a circle in FIG. “T1”, “T2”, “T3”, “T4”, “23-6”, “6-10”, “10-16”, “16-23” and circles are shown in FIG. 5 and FIG. 8 is used similarly to FIG.

  The time for which each of the plurality of loads 7 is used may be set in units of 30 minutes, 15 minutes, or 1 minute, for example. The information on weekdays in FIG. 4 may be replaced with a collection of information about each individual day on Monday, Tuesday, Wednesday, Thursday and Friday, and the information on holidays in FIG. It may be replaced with a collection of information about each individual day. The information about the season in the figure may be replaced with a collection of information about each of the 12 individual months that make up the year, or information about each of the 52 individual weeks that make up the year. May be replaced by a collection of

  The information shown in FIG. 4 will be specifically described below. FIG. 4 shows the following information about the first cooling device. That is, the power consumption of the first cooling device is 2 kilowatts. The first cooling device is used by the father and mother in the midnight time zone T1, the morning time zone T2 and the night time zone T4 on weekdays, and in the late night time zone T1, morning time zone T2 and daytime time on holidays. Used by father and mother in band T3 and night time band T4. The first cooling device is used in summer.

  FIG. 4 shows the following information about the second cooling device. That is, the power consumption of the second cooling device is 1 kilowatt, and the second cooling device is used by the child in the late-night time zone T1 on both weekdays and holidays. The second cooling device is used in summer.

  FIG. 4 shows the following information about the first heating appliance. That is, the power consumption of the first heating device is 2 kilowatts. The first heating device is used by the father and mother in the midnight time zone T1, the morning time zone T2 and the night time zone T4 on weekdays, and in the late night time zone T1, the morning time zone T2 and the daytime time on holidays. Used by father and mother in band T3 and night time band T4. The first heating device is used in winter.

  FIG. 4 shows the following information about the second heating appliance. That is, the power consumption of the second heating device is 1 kilowatt. The second heating device is used by the child in the late-night time zone T1 on both weekdays and holidays. The second heating device is used in winter.

  FIG. 4 shows the following information about the television set and personal computer. That is, the power consumption of the television set and personal computer is 0.5 kilowatt. Television sets and personal computers are used by fathers, mothers and children at night time T4 on weekdays, and fathers, mothers and children at morning time T2, day time T3 and night time T4 on holidays. Used by. Television sets and personal computers are used in spring, summer, autumn and winter. In FIG. 4, 0.5 kilowatts of power consumption of the television set and the personal computer means the sum of the power consumption of the television set and the power consumption of the personal computer.

  FIG. 4 shows the following information about the cooking utensil. That is, the power consumption of the cooking utensil is 1 kilowatt. The cookware is used by the mother on weekdays in the morning time zone T2 and night time zone T4, and on holidays, it is used by the mother in the morning time zone T2, daytime time zone T3, and night time zone T4. Cookware is used in spring, summer, autumn and winter.

  FIG. 4 shows the following information about the lighting device. That is, the power consumption of the lighting device is 0.5 kilowatt. The lighting equipment is used by the father, mother and child in the morning time zone T2 and the night time zone T4 on both weekdays and holidays. Lighting equipment is used in spring, summer, autumn and winter.

  FIG. 5 is a diagram illustrating information for explaining the operation of the power control apparatus 1 according to the embodiment. Information shown in FIG. 5 is stored in the storage unit 16. FIG. 5 includes a part of the information shown in FIG. FIG. 5 shows the following information about the first cooling device. That is, the power consumption of the first cooling device is 2 kilowatts. The first cooling device is used in the late-night time zone T1, the morning time zone T2, and the night time zone T4 on weekdays, and on the holiday, the late-night time zone T1, the morning time zone T2, the daytime time zone T3, and the night time. Is used for the time period T4. The first cooling device is used only in summer.

  FIG. 5 shows the following information about the second cooling device. That is, the power consumption of the second cooling device is 1 kilowatt. The second cooling device is used in the late-night time zone T1 on both weekdays and holidays. The second cooling device is used only in summer.

  FIG. 5 shows the following information about the television set and personal computer. That is, the power consumption of the television set and personal computer is 0.5 kilowatt. The television set and personal computer are used in the night time zone T4 on weekdays, and in the morning time zone T2, noon time zone T3, and night time zone T4 on holidays. In FIG. 5, 0.5 kilowatts of power consumption of the television set and the personal computer means the sum of the power consumption of the television set and the power consumption of the personal computer.

  FIG. 5 further shows information on the required power amount for each time zone in summer and information on the required power amount for each time zone in spring and autumn. The unit of the required electric energy is kilowatt hour. In FIG. 5, the kilowatt hour is described as “kWh”. That is, FIG. 5 shows that on a summer weekday, the required power amount in the late-night time zone T1 is 3 kWh, the required power amount in the morning time zone T2 is 2 kWh, and the required power amount in the daytime time zone T3 is 0 kWh. It shows that the required power amount in the night time zone T4 is 2.5 kWh.

  On summer weekdays, the required amount of power during the daytime period T3 is 0 kWh because the user is not in the house 2 for work or school life, and the first air conditioner, the second air conditioner, the television set, and This is because the personal computer is not used. FIG. 5 shows that on a summer holiday, the required power amount in the late-night time zone T1 is 3 kWh, and the required power amounts in the morning time zone T2, the noon time zone T3, and the night time zone T4 are 2.5 kWh. It is shown that.

  FIG. 5 shows that on weekdays in spring and autumn, the required power amount of each of the midnight time zone T1, the morning time zone T2, and the daytime time zone T3 is 0 kWh, and the required power amount of the night time zone T4 is 0. .5 kWh. FIG. 5 shows that on spring and autumn holidays, the required power amount in the late-night time zone T1 is 0 kWh, and the required power amounts in the morning time zone T2, the daytime time zone T3, and the night time zone T4 are 0. .5 kWh.

  FIG. 5 shows that the price of the electric power supplied from the electric power company to the house 2 is relatively low in the midnight time zone T1 in the row where the character string “electricity charge” is written, both on weekdays and on holidays. This shows that the price of power supplied from the power company to the house 2 is relatively high in each of the morning time zone T2, the daytime time zone T3, and the night time zone T4. In FIG. 5, it is shown that the price of the power supplied from the power company to the house 2 is one of two cases, a low case and a high case. However, the price of power supplied from the power company to the house 2 in each of the late-night time zone T1, the morning time zone T2, the daytime time zone T3, and the night time zone T4 is, for example, three or more prices. Any one price may be different.

  Next, an example of the operation of the power control apparatus 1 will be described. FIG. 6 is a flowchart illustrating a part of an example of the operation of the power control apparatus 1 according to the embodiment. FIG. 7 is a flowchart illustrating the remainder of the procedure of an example of the operation of the power control apparatus 1 according to the embodiment. In the example described using the flowcharts of FIGS. 6 and 7, it is assumed that the power control apparatus 1 operates every day based on the information shown in FIG.

  The control unit 15 of the power control apparatus 1 acquires data from the storage unit 16 (S1). That is, the control unit 15 acquires the load data 21, the season data 22, the day of the week time data 23, the user data 24, and the weather data 25 from the storage unit 16 (S1). The data acquired by the control unit 15 from the storage unit 16 includes the information of FIG. The data acquired from the storage unit 16 by the control unit 15 includes usage time data indicating the time during which the load 7 is used for each time zone on the target date of charging and discharging of the storage battery 5 by the power control device 1.

  Based on the data acquired in step S1, the control unit 15 calculates the power consumption of each load 7 in the midnight time zone T1, the morning time zone T2, the daytime time zone T3, and the night time zone T4. (S2). That is, the control unit 15 uses the power consumption P1 of the load 7 in the midnight time zone T1, the power consumption P2 of the load 7 in the morning time zone T2, and the power consumption P3 of the load 7 in the daytime time zone T3. Then, the power consumption amount P4 of the load 7 in the night time zone T4 is calculated (S2). Furthermore, the control unit 15 calculates the power consumption amount of the load 7 based on the load data 21 and the usage time data.

  The power consumption amount P1 of the load 7 in the midnight time zone T1 is the necessary power amount in the midnight time zone T1. The power consumption amount P2 of the load 7 in the morning time zone T2 is a necessary power amount in the morning time zone T2. The power consumption amount P3 of the load 7 in the daytime time zone T3 is a necessary power amount in the daytime time zone T3. The power consumption amount P4 of the load 7 in the night time zone T4 is a necessary power amount in the night time zone T4.

  Based on the weather forecast data included in the weather data 25 acquired in step S1, the control unit 15 is sunny and daylight in the daytime time zone T3 of the day subject to charge and discharge control of the storage battery 5. It is determined whether or not the panel 3 generates power based on sunlight (S3). Hereinafter, “the date of control of charging and discharging of the storage battery 5” is simply referred to as “the date of control”. That is, the control unit 15 determines whether or not solar power generation is performed in the daytime time zone T3 of the day to be controlled (S3). When it is determined that the solar power generation is performed in the daytime time zone T3 of the day to be controlled (Yes in S3), the control unit 15 performs the operation of Step S10 in FIG. The operation of step S10 will be described later.

  When solar power generation is not performed in the daytime time zone T3 of the day to be controlled, the power control device 1 is used for the midnight time in order to make the cost for the power consumed by the load 7 as low as possible. The belt T1 receives a part or all of the necessary power on the day to be controlled via the power system 6 by power purchase and stores it in the storage battery 5. When the control unit 15 determines that solar power generation is not performed in the daytime time zone T3 of the day to be controlled (No in S3), the morning time zone T2, the daytime time zone T3, and the night time zone. The required power amount of T4 is calculated (S4).

  That is, the control unit 15 uses the power consumption P2 of the load 7 in the morning time zone T2, the power consumption P3 of the load 7 in the daytime time zone T3, and the power consumption P4 of the load 7 in the night time zone T4. Is calculated (S4). Regarding the power consumption amount P1 of the load 7 in the midnight time zone T1, the power control device 1 does not allocate the power stored in the storage battery 5 to the power consumption power P1 from the power company 6 through the power system 6. A part of the AC power supplied to the house 2 is allocated to the power consumed by the load 7.

  When the control unit 15 determines that solar power generation is not performed in the daytime time zone T3 of the day to be controlled (No in S3), the amount of power that can be stored in the storage battery 5 in the late night time zone T1. The chargeable power amount C1 is calculated (S4). The power stored in the storage battery 5 in the midnight time zone T <b> 1 is only power based on the power supplied from the power company to the house 2 through the power system 6. The price of power supplied from the power company to the house 2 in the late-night time period T1 is relatively low. The power supplied from the power company to the house 2 via the power system 6 in the midnight time zone T1 is also consumed for using the load 7. Therefore, in step S4, the control unit 15 calculates the chargeable electric energy C1 using the formula “C1 = (contract power × time of midnight time period T1−P1)”.

  The control unit 15 determines whether or not the sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is larger than the chargeable power amount C1 (S5). When the sum is less than or equal to the chargeable power amount C1 (No in S5), the power of the chargeable power amount C1 stored in the storage battery 5 in the morning time zone T2, the daytime time zone T3, and the night time zone T4 Thus, the load 7 can be operated. Therefore, when the control unit 15 determines that the sum is equal to or less than the chargeable power amount C1 (No in S5), the control unit 15 applies power to the DC / AC conversion circuit 14 of the power control device 1 in the midnight time zone T1. A part of the AC power from 6 is converted into DC power, and the DC power obtained by the conversion is controlled to be output to the storage battery charging / discharging circuit 13.

  In addition, the control unit 15 is a power based on the power from the DC / AC conversion circuit 14 with respect to the storage battery charging / discharging circuit 13 of the power control device 1 in the midnight time zone T1, and the power consumption P2 And the control which makes the storage battery 5 store the electric power of the electric energy equal to the sum of the electric power consumption P3 and the electric power consumption P4 is performed (S6). That is, when the power consumption amount of the load 7 in the time zone other than the midnight time zone T1 on the control target day is equal to or less than the chargeable power amount C1, the control unit 15 sets the midnight time zone on the control target day. Control is performed to store in the storage battery 5 the amount of power consumed by the load 7 in a time zone other than T1 (S6). In the midnight time zone T <b> 1, the DC / AC conversion circuit 14 converts part of the AC power from the power system 6 into DC power and outputs the DC power to the storage battery charging / discharging circuit 13.

  In the midnight time zone T1, the storage battery charging / discharging circuit 13 is based on the power from the DC / AC conversion circuit 14, and includes the power consumption P2, the power consumption P3, and the power consumption P4. The storage battery 5 is made to store the amount of power equal to the sum (S6). The storage battery charging / discharging circuit 13 causes the storage battery 5 to store DC power having a voltage suitable for the storage battery 5 when the storage battery 5 stores power. It is the electric power based on the electric power from the DC / AC conversion circuit 14, and the electric power exceeding the electric energy equal to the sum of the electric energy consumption P2, the electric energy consumption P3, and the electric energy consumption P4 is stored in the storage battery 5. Even if it can be stored, storing the power exceeding the amount of power equal to the sum in the storage battery 5 is performed because it is impossible to purchase unnecessary power and use up the unnecessary power. Absent.

  In the midnight time zone T1, the control unit 15 corresponds to the load 7 the voltage of the AC power from the power system 6 with respect to the DC to AC conversion circuit 14 for the power consumption P1 of the load 7 in the midnight time zone T1. Control is performed to convert the voltage into voltage and output the AC power obtained by the conversion to the load 7. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7. That is, in the midnight time zone T1, the control unit 15 allocates the AC power from the power system 6 to the power consumption P1 in the midnight time zone T1 (S6).

  In the morning time zone T2, the daytime time zone T3, and the night time zone T4, the control unit 15 controls the storage battery charging / discharging circuit 13 to discharge the storage battery 5 (S7). In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. That is, the control unit 15 has a function of performing control to allocate the power released from the storage battery 5 to the power consumed by the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S7). The storage battery 5 is discharged by the control by the storage battery charging / discharging circuit 13 (S7).

  The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 of the power control device 1 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7. In the morning time zone T2, the daytime time zone T3, and the night time zone T4 in step S7, the power stored in the storage battery 5 is consumed, and the AC power from the power system 6 is not consumed. As a result, the user does not have to purchase power from the power company during a time period when the price is relatively high.

  When the control unit 15 determines that the sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is larger than the chargeable power amount C1 (Yes in S5), the control unit 15 performs DC in the midnight time zone T1. The AC conversion circuit 14 is controlled to convert a part of AC power from the power system 6 into DC power and output it to the storage battery charging / discharging circuit 13. In addition, the control unit 15 controls the storage battery charging / discharging circuit 13 to store in the storage battery 5 either the power up to the limit of the capacity of the storage battery 5 or the chargeable power amount C1 (S8). . The power up to the limit of the capacity of the storage battery 5 and the power of the chargeable power amount C <b> 1 are power supplied from the DC / AC conversion circuit 14.

  In step S <b> 8, the DC / AC conversion circuit 14 converts AC power from the power system 6 into DC power and outputs the DC power to the storage battery charging / discharging circuit 13. The storage battery charging / discharging circuit 13 causes the storage battery 5 to store either the power up to the limit of the capacity of the storage battery 5 or the power of the chargeable power amount C1. The power up to the limit of the capacity of the storage battery 5 and the power of the chargeable power amount C <b> 1 are power supplied from the DC / AC conversion circuit 14. Even if the power up to the limit of the capacity of the storage battery 5 or the chargeable power amount C1 is stored in the storage battery 5, only the power stored in the storage battery 5 can be used in the morning time zone T2, the daytime time zone T3, and the night time. The amount of power required for the time zone T4 cannot be covered. However, since there is a restriction on the amount of power that can be stored in the storage battery 5, the power up to the limit of the capacity of the storage battery 5 or the chargeable power amount C <b> 1 is stored in the storage battery 5.

  The control unit 15 corresponds to the load 7 with the voltage of the AC power from the power system 6 with respect to the DC / AC conversion circuit 14 for the power consumption P1 of the load 7 in the midnight time zone T1 in the midnight time zone T1. Control is performed to convert the voltage into voltage and output the AC power obtained by the conversion to the load 7. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7. That is, in the midnight time zone T1, the control unit 15 allocates a part of the AC power from the power grid 6 to the power consumption P1 in the midnight time zone T1 (S8). Through the operations from step S6 to step S8, the power control apparatus 1 can allocate cheaper power to the power consumed by the load 7.

  In the morning time zone T2, the daytime time zone T3, and the night time zone T4, the control unit 15 controls the storage battery 5 to discharge the storage battery 5 (S9). In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S9). The storage battery 5 is discharged by the control by the storage battery charging / discharging circuit 13 (S9). The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  In the morning time zone T2, the daytime time zone T3, and the night time zone T4, when the remaining amount of power stored in the storage battery 5 by discharge becomes equal to or less than a predetermined value, the control unit 15 charges the storage battery. The discharge circuit 13 is controlled to stop the storage battery 5 from discharging. In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7 and to output the AC power obtained by the conversion to the load 7. Do. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7. That is, in the morning time zone T2, the daytime time zone T3, and the night time zone T4, the control unit 15 allocates the AC power from the power system 6 to the power consumption amount that is insufficient (S9).

  When the control unit 15 determines that solar power generation is performed in the daytime time zone T3 of the day to be controlled (Yes in S3), the power consumption amount P1 of the load 7 in the late night time zone T1 and the morning time Calculate the total power consumption of the power consumption P2 of the load 7 in the time zone T2, the power consumption P3 of the load 7 in the daytime time zone T3, and the power consumption P4 of the load 7 in the night time zone T4. (S10).

  In addition, the control unit 15 estimates the amount of power obtained by the solar panel 3 generating power based on sunlight during the daytime period T3 (S10). Hereinafter, the estimated “amount of power obtained by the solar panel 3 generating power based on sunlight in the daytime time period T3” is described as the estimated solar power generation amount G. The control unit 15 determines whether or not the total power consumption amount of the power consumption amount P1, the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is larger than the estimated solar power generation amount G ( S11). More specifically, in step S11, the control unit 15 determines that the amount of power obtained from the solar module 4 on the control target day is 24 after the time when solar power generation on the control target day is started. It is determined whether or not the amount of power consumption of the load 7 over time is larger.

  When the total power consumption is less than or equal to the estimated solar power generation amount G (No in S11), the solar panel 3 uses the solar panel 3 to calculate the power required in all time zones on the day of control. It can be covered only with the power obtained by generating electricity. Therefore, if the control unit 15 determines that the total power consumption is equal to or less than the estimated solar power generation amount G (No in S11), the control unit 15 causes the DC voltage conversion circuit 12 of the power control device 1 to be in the daytime time zone T3. On the other hand, the solar panel 3 performs control to convert the voltage of the DC power from the solar module 4 obtained by generating power based on sunlight into a constant voltage.

  In addition, the control unit 15 provides the storage battery charging / discharging circuit 13 with power having an amount of power equal to the sum of the power consumption amount P1, the power consumption amount P2, and the power consumption amount P4 in the daytime period T3. Control is performed to store in the storage battery 5 the power that is one of the power up to the limit of the capacity of the storage battery 5 and is generated by the solar panel 3 based on sunlight (S12).

  In the daytime period T3 of step S12, the DC voltage conversion circuit 12 converts the voltage of DC power from the solar module 4 obtained by the solar panel 3 generating power based on sunlight into a constant voltage. Then, a part of the obtained electric power is output to the storage battery charging / discharging circuit 13. The storage battery charging / discharging circuit 13 is one power of the power consumption equal to the sum of the power consumption P1, the power consumption P2, and the power consumption P4, and the power up to the capacity limit of the storage battery 5. Then, a part of the electric power obtained by the solar panel 3 generating electricity based on sunlight is stored in the storage battery 5 (S12). The storage battery charging / discharging circuit 13 causes the storage battery 5 to store DC power having a voltage suitable for the storage battery 5 when the storage battery 5 stores power.

  In the daytime period T3, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power obtained by the DC voltage conversion circuit 12 into AC power and output it to the load 7 for the power consumption P3. I do. The DC voltage conversion circuit 12 outputs a part of DC power obtained by the solar panel 3 generating power based on sunlight to the DC voltage conversion circuit 12. The DC / AC conversion circuit 14 converts a part of the DC power obtained by the DC voltage conversion circuit 12 into AC power and outputs the AC power to the load 7. That is, in the daytime period T3, the control unit 15 allocates a part of the DC power obtained by the photovoltaic power generation to the power consumption P3 in the daytime period T3 (S12).

  In the late-night time zone T1, the morning time zone T2, and the night time zone T4 in which the solar panel 3 does not generate power, the control unit 15 controls the storage battery 5 to discharge the storage battery 5 ( S12). In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S12). The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  Furthermore, in step S11, the control unit 15 determines that the amount of power obtained from the solar module 4 on the day of control is 24 hours after the start of solar power generation on the day of control. When it is determined whether or not the amount of power consumed by the load 7 is equal to or greater than the amount of power consumed by the solar module 4, the following operation is performed. That is, the control unit 15 uses the power consumption of the load 7 after the end of the solar power generation in the 24-hour period T3, which is the time zone during which solar power generation is performed on the day to be controlled. The storage battery 5 is made to store the amount of power corresponding to the amount. In addition, the control unit 15 allocates a part of the power obtained from the solar module 4 to the power consumed by the load 7 in the daytime time zone T3 in the daytime time zone T3.

  Furthermore, the control part 15 is the control which makes the storage battery 5 discharge in the time slot | zone after the time of the solar power generation of the control object day, and allocates the electric power discharge | released from the storage battery 5 to the electric power which the load 7 consumes. I do. There are three time zones after the end of solar power generation on the day to be controlled: continuous night time zone T4 after day time zone T3, late night time zone T1 and morning time zone T2. It is a time zone. That is, when the amount of power obtained by photovoltaic power generation on the day of control is equal to or greater than the power consumption of load 7 in 24 hours after the start of photovoltaic power generation on the day of control, The power control device 1 can allocate free power to power consumed by the load 7 in 24 hours after the start of photovoltaic power generation.

  When the total power consumption amount of the power consumption amount P1, the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is larger than the estimated solar power generation amount G (Yes in S11), the control target day It is not possible to cover only the power obtained by the solar panel 3 generating power based on the sunlight. When it is determined that the total power consumption is greater than the estimated solar power generation amount G (Yes in S11), the control unit 15 is a small sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4. It is determined whether or not the power consumption amount is less than the estimated solar power generation amount G (S13). That is, if the control unit 15 determines that the total power consumption is greater than the estimated solar power generation amount G (Yes in S11), the morning time zone T2 when the price of power from the power company is relatively high, The amount of power required in the daytime period T3 and the nighttime period T4 is compared with the estimated solar power generation amount G (S13).

  When the small total power consumption is equal to or greater than the estimated solar power generation amount G (No in S13), only the power of the estimated solar power generation amount G is the morning time zone T2, the noon time zone T3, and the night time zone T4. It is not possible to cover the amount of power required for When the control unit 15 determines that the small total power consumption is equal to or greater than the estimated solar power generation amount G (No in S13), the control unit 15 transmits the power consumption P1 to the DC-AC conversion circuit 14 in the midnight time zone T1. On the other hand, control is performed to convert the voltage of AC power from the power system 6 into a voltage corresponding to the load 7 and output the AC power obtained by the conversion to the load 7.

  In the midnight time zone T1, for the power consumption P1, the DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and the AC power obtained by the conversion is supplied to the load 7. Output. That is, in the midnight time zone T1, the control unit 15 assigns the AC power from the power system 6 to the power consumption P1 in the midnight time zone T1 (S14).

  In addition, the control unit 15 calculates the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 from a small sum with respect to the storage battery charging / discharging circuit 13 and the DC / AC conversion circuit 14 in the midnight time zone T1. Control is performed to store in the storage battery 5 either the amount of power obtained by subtracting the estimated solar power generation amount G or the power up to the capacity limit of the storage battery 5 (S14). In the late-night time period T1, the DC / AC conversion circuit 14 uses the amount of AC power from the power system 6 by subtracting the estimated solar power generation amount G from the small total and the power up to the limit of the capacity of the storage battery 5. Convert to either DC power. The storage battery charging / discharging circuit 13 is a DC power obtained by the DC / AC conversion circuit 14, and is either an amount of power obtained by subtracting the estimated solar power generation amount G from a small sum and a power up to the capacity limit of the storage battery 5. One electric power is stored in the storage battery 5 (S14).

  In the morning time zone T2 and the night time zone T4, the control unit 15 controls the storage battery charging / discharging circuit 13 to discharge the storage battery 5 (S14). In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S14). The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  In the morning time zone T2 and the night time zone T4, when the power stored in the storage battery 5 is completely consumed by the discharge, the control unit 15 causes the AC to AC power from the power system 6 to the DC to AC conversion circuit 14. Control is performed to convert the voltage of the power into a voltage corresponding to the load 7 and to output the AC power obtained by the conversion to the load 7. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7.

  In the daytime period T3, the control unit 15 uses the DC voltage conversion circuit 12 to generate a voltage of DC power from the solar module 4 that is obtained when the solar panel 3 generates power based on sunlight. Control to convert to. In addition, the control unit 15 converts the DC power obtained by the DC voltage conversion circuit 12 into AC power with respect to the DC / AC conversion circuit 14 for the power consumption P3 of the load 7 in the daytime period T3, and converts the load 7 Control to output to. The DC voltage conversion circuit 12 converts the voltage of the DC power from the solar module 4 into a constant voltage, and the DC / AC conversion circuit 14 converts the DC power obtained by the DC voltage conversion circuit 12 into AC power to load 7. Output to. That is, in the daytime period T3, the control unit 15 allocates a part of the DC power obtained by the solar power generation to the power consumption P3 in the daytime period T3 (S14).

  In the daytime period T3, when the amount of DC power from the solar module 4 is larger than the amount of power required by the load 7, that is, the amount of DC power from the solar module 4 is larger than the power consumption P3. In this case, the control unit 15 causes the storage battery charging / discharging circuit 13 to store in the storage battery 5 the power of the difference between the amount of DC power from the solar module 4 and the amount of power required by the load 7. I do. The storage battery charging / discharging circuit 13 causes the storage battery 5 to store the amount of power corresponding to the difference.

  When the amount of DC power from the solar module 4 is less than the amount of power required by the load 7, that is, when the amount of DC power from the solar module 4 is less than the power consumption P3, the control unit 15 The storage battery charging / discharging circuit 13 is controlled to discharge the storage battery 5. In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge. The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  When the power stored in the storage battery 5 is consumed by the discharge in the daytime period T3, the control unit 15 applies the voltage of the AC power from the power system 6 to the load 7 with respect to the DC / AC conversion circuit 14. Is converted to a voltage corresponding to, and AC power obtained by the conversion is output to the load 7. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7.

  When the small total power consumption amount of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is smaller than the estimated solar power generation amount G (Yes in S13), the morning time zone T2 and the daytime time zone Electric power necessary for T3 and night time period T4 can be covered with electric power obtained by solar power generation. When the control unit 15 determines that the small total power consumption amount of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is less than the estimated solar power generation amount G (Yes in S13), In the time zone T1, when the amount of power stored in the storage battery 5 is equal to or greater than the power consumption P2, the storage battery charging / discharging circuit 13 is controlled to discharge the storage battery 5 (S15).

  In addition, in the midnight time zone T1, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S15). The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  In the midnight time zone T1, when the amount of power stored in the storage battery 5 is less than the power consumption amount P2, or the power stored in the storage battery 5 is consumed, the power amount of the storage battery 5 becomes the power consumption amount P2. When it has reached, the control unit 15 controls the storage battery charging / discharging circuit 13 so that the storage battery 5 is not discharged. In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7 and to output the AC power obtained by the conversion to the load 7. Do. The storage battery charging / discharging circuit 13 stops the discharge of the storage battery 5. The DC / AC conversion circuit 14 converts the voltage of the AC power from the power system 6 into a voltage corresponding to the load 7, and outputs the obtained AC power to the load 7.

  In the morning time zone T2 and the night time zone T4, the control unit 15 controls the storage battery charging / discharging circuit 13 to discharge the storage battery 5 (S15). In addition, the control unit 15 controls the DC / AC conversion circuit 14 to convert the DC power discharged from the storage battery 5 into AC power and output it to the load 7. The storage battery charging / discharging circuit 13 causes the storage battery 5 to discharge (S15). The DC power released from the storage battery 5 is received by the DC / AC conversion circuit 14 via the storage battery charging / discharging circuit 13. The DC / AC conversion circuit 14 converts the received DC power into AC power and outputs the obtained AC power to the load 7.

  In the daytime period T3, the control unit 15 uses the DC voltage conversion circuit 12 to generate a voltage of DC power from the solar module 4 that is obtained when the solar panel 3 generates power based on sunlight. Control to convert to. In addition, the control unit 15 converts the DC power obtained by the DC voltage conversion circuit 12 into AC power with respect to the DC / AC conversion circuit 14 for the power consumption P3 of the load 7 in the daytime period T3. 7 is controlled.

  The DC voltage conversion circuit 12 converts the voltage of the DC power from the solar module 4 into a constant voltage, and the DC / AC conversion circuit 14 converts the DC power obtained by the DC voltage conversion circuit 12 into AC power for the power consumption P3. And output to the load 7. That is, in the daytime period T3, the control unit 15 allocates a part of the DC power obtained by the photovoltaic power generation to the power consumption P3 in the daytime period T3 (S15).

  In the daytime period T3, the control unit 15 causes the storage battery charging / discharging circuit 13 to store the power of the difference between the amount of DC power from the solar module 4 and the amount of power required by the load 7 for the storage battery. 5 is stored (S15). That is, the control unit 15 controls the storage battery charging / discharging circuit 13 to store in the storage battery 5 the power of the difference between the amount of DC power from the solar module 4 and the power consumption P3 (S15). The storage battery charging / discharging circuit 13 causes the storage battery 5 to store the amount of power corresponding to the difference from the DC voltage conversion circuit 12 (S15). That is, in the daytime time zone T3, the control unit 15 causes the storage battery 5 to store a part of the DC power obtained by solar power generation (S15).

  The operation of the power control apparatus 1 described with reference to the flowcharts of FIG. 6 and FIG. 7 described above is performed not only on the control target day but also every day, for example. By performing this operation every day, the user can use the cheapest power without switching the control method. Actually, since the home appliances that consume a certain amount of power for 24 hours are included in the plurality of loads 7, it is necessary to consider the amount of power consumed by the home appliances. By subtracting the certain amount from the capacity of the storage battery 5, it is possible to cope with the power consumed by the home appliance. An example of a home appliance that consumes a certain amount of power for 24 hours is a refrigerator or a ventilator.

  FIG. 8 is a diagram illustrating an example of the transition of the capacity of the electric power stored in the storage battery 5 by the control by the power control device 1 according to the embodiment. FIG. 8 includes a part of the information shown in FIG. In the example of FIG. 8, the first cooling device, the second cooling device, the television set, and the personal computer are used in a time zone that is circled. It is assumed that the amount of power obtained by the solar panel 3 generating power based on sunlight in the daytime time zone T3 is 4 kWh. That is, it is assumed that the estimated solar power generation amount G, which is the estimated “amount of power obtained by the solar panel 3 generating power based on sunlight in the daytime period T3”, is 4 kWh. The required power amount in FIG. 8 means the power consumption amount.

  In the example of FIG. 8, on summer weekdays, the power consumption P1 is 3 kWh, the power consumption P2 is 2 kWh, the power consumption P3 is 0 kWh, and the power consumption P4 is 2.5 kWh. On summer holidays, the power consumption P1 is 3 kWh, and each of the power consumption P2, the power consumption P3, and the power consumption P4 is 2.5 kWh. On weekdays in spring and autumn, each of the power consumption P1, the power consumption P2, and the power consumption P3 is 0 kWh, and the power consumption P4 is 0.5 kWh. On spring and autumn holidays, the power consumption P1 is 0 kWh, and each of the power consumption P2, the power consumption P3, and the power consumption P4 is 0.5 kWh.

  The total power consumption of a summer weekday is 7 kWh, which is a total of 3 kWh of power consumption P1, 2 kWh of power consumption P2, 0 kWh of power consumption P3, and 2.5 kWh of power consumption P4. .5 kWh. When it is sunny on weekdays in summer, the total power consumption per day is larger than the estimated solar power generation amount G. In step S11 of the second flowchart of FIG. 7, a determination result of “Yes” is obtained, and the operation of step S13 is performed.

  A small sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is 4.5 kWh. Therefore, in step S13, a determination result of “No” is obtained, and the operation of step S14 is performed. In step S <b> 14, in the midnight time zone T <b> 1, the amount of power calculated by the expression “P2 + P3 + P4-G” is stored in the storage battery 5. This equation is an equation indicating that the estimated solar power generation amount G is subtracted from the small sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4. That is, when the estimated solar power generation amount G is 4 kWh, 0.5 kWh electric power calculated by the formula “2 kWh + 0 kWh + 2.5 kWh−4 kWh” is stored in the storage battery 5 in the late-night time zone T1. The 0.5 kWh power stored in the storage battery 5 is DC power based on AC power supplied from the power system 6.

  When 1.5 kWh of electric power is stored in the storage battery 5 at the start of the midnight time zone T1, the storage battery 5 is stored at the end of the midnight time zone T1 and the start of the morning time zone T2. The capacity of the stored electric power is 2.0 kWh. Since 2.0 kWh is the same as the power consumption P2 in the morning time zone T2, the power stored in the storage battery 5 at the start of the morning time zone T2 is the same as that at the end of the morning time zone T2. It is consumed up.

  Since the power consumption amount P3 in the daytime period T3 is 0 kWh, all of the power generation amount 4 kWh obtained by solar power generation is stored in the storage battery 5. As a result, the capacity of the electric power stored in the storage battery 5 is 4 kWh at the end of the daytime period T3 and the start of the nighttime period T4. Since the power consumption P4 in the night time zone T4 is 2.5 kWh, the capacity of the power stored in the storage battery 5 at the end of the night time zone T4 is 1.5 kWh.

  In the upper row of the line including the character string “battery capacity (kWh)” in FIG. 8, the above-mentioned summer weekday midnight time zone T1, morning time zone T2, daytime time zone T3, and night time zone T4. The transition of the capacity of the storage battery 5 in each is shown using arrows.

  On summer holidays, the total daily power consumption is 3 kWh for power consumption P1, 2.5 kWh for power consumption P2, 2.5 kWh for power consumption P3, and 2.5 kWh for power consumption P4. And 10.5 kWh in total. When it is sunny on a summer holiday, the total daily power consumption is greater than the estimated solar power generation amount G. In step S11 of the second flowchart of FIG. 7, a determination result of “Yes” is obtained, and the operation of step S13 is performed.

  A small sum of the power consumption amount P2, the power consumption amount P3, and the power consumption amount P4 is 7.5 kWh. Therefore, in step S13, a determination result of “No” is obtained, and the operation of step S14 is performed. In step S <b> 14, in the midnight time zone T <b> 1, the amount of power calculated by the expression “P2 + P3 + P4-G” is stored in the storage battery 5. That is, when the estimated solar power generation amount G is 4 kWh, 3.5 kWh electric power calculated by the formula of “2.5 kWh + 2.5 kWh + 2.5 kWh-4 kWh” is stored in the storage battery 5 in the late-night time zone T1. The 3.5 kWh power stored in the storage battery 5 is DC power based on AC power supplied from the power system 6.

  When the capacity of the electric power stored in the storage battery 5 is zero at the start of the midnight time zone T1, the storage battery 5 is used at the end of the midnight time zone T1 and the start of the morning time zone T2. The capacity of the power stored in is 3.5 kWh. Since the power consumption P2 in the morning time zone T2 is 2.5 kWh, the capacity of the electric power stored in the storage battery 5 at the end of the morning time zone T2 and the start of the daytime time zone T3 is 1.0 kWh.

  In the daytime time zone T3, the amount of power generated by sunlight is 4 kWh and the amount of power consumption P3 is 2.5 kWh, so a part of the power obtained by the photovoltaic power generation is allocated to the power consumption P3. . Power of 1.5 kWh, which is the amount of power obtained by subtracting the amount of power consumption P3 from the amount of power obtained by solar power generation, is stored in the storage battery 5. As described above, since the capacity of the electric power stored in the storage battery 5 at the start of the daytime period T3 was 1.0 kWh, the end of the daytime period T3 and the start of the nighttime period T4 The capacity of the electric power stored in the storage battery 5 at the time of is 2.5 kWh.

  The power consumption P4 in the night time zone T4 is 2.5 kWh. Therefore, the capacity of the electric power stored in the storage battery 5 at the end of the night time zone T4 and the start of the late night time zone T1 is 0 kWh.

  In the upper row of the line including the character string “battery capacity (kWh)” in FIG. 8, the above-mentioned summer holiday midnight time zone T1, morning time zone T2, daytime time zone T3 and night time zone T4 The transition of the capacity of the storage battery 5 in each is shown using arrows.

  In the lower part of the row including the character string “battery capacity (kWh)” in FIG. 8, as with the transition of the capacity of the storage battery 5 in summer, the time zone T1 in the spring weekdays and the midnight, the time zone T2 in the morning, the daytime The transition of the capacity of the storage battery 5 in each of the time zone T3 and the night time zone T4 is shown using arrows.

  In the upper part of the row including the character string “battery operation” in FIG. 8, the storage battery in each of the summer weekday and midnight time zone T1, the morning time zone T2, the daytime time zone T3, and the night time zone T4. Information of operation 5 is shown. The character string “charging / stopping” indicates that charging stops after the storage battery 5 is charged. The character string “discharge” indicates that the storage battery 5 is discharged. The character string “charging” indicates that electric power is stored in the storage battery 5. In the charging of the storage battery 5, for example, power of 2 kWh per hour is stored in the storage battery 5.

  In the lower part of the line including the character string “battery operation” in FIG. 8, the time zone T1, the morning time zone T2, the morning time zone, the daytime time zone in the spring weekdays and the holidays, as well as the operation information of the summer storage battery 5 Information on the operation of the storage battery 5 in each of T3 and night time zone T4 is shown.

  As described above, the power control device 1 causes the storage battery 5 to store power based on the power obtained by solar power generation and the power supplied from the power company to the house 2 in the midnight time zone T1. An example of the transition of the capacity of the electric power stored in the storage battery 5 is shown in a line including the character string “battery capacity (kWh)” in FIG. When the load 7 operates in the daytime time zone T3, the power control apparatus 1 uses the power stored in the storage battery 5, and the energy loss due to the conversion for the power is converted for the power obtained by solar power generation. Therefore, the power based on the power obtained by solar power generation is output to the load 7 without using the power stored in the storage battery 5. Thereby, it can suppress that the loss of energy by power conversion arises. The power control device 1 causes the storage battery 5 to store DC power based on the AC power supplied from the power system 6 when the storage battery 5 stores power in the midnight time zone T1.

  When the day before the control target day is a weekday and the control target day is a holiday, the power control device 1 manages the capacity of the storage battery 5 in consideration of the required power amount for the holiday. When the previous day of the control target day is a holiday and the control target day is a weekday, the power control device 1 manages the capacity of the storage battery 5 in consideration of the required power amount on weekdays.

  FIG. 9 is a diagram showing an example of the transition of power consumption during summer weekdays and holidays. FIG. 10 is a diagram illustrating an example of the transition of power consumption during weekdays and holidays on spring and autumn. 9 and 10 show changes in power consumption every hour. FIG. 8 shows that the power consumption amount for 7 hours is 3 kWh in the late-night time zone T1 of summer weekdays, so the power consumption amount per hour is 0.43 kWh. Since FIG. 9 shows that the power consumption per hour is 0.43 kWh in the midnight time zone T1, there is no contradiction between FIG. 8 and FIG. The late-night time zone T1 is a 7-hour time zone from 23:00 on the day before any given day to 6 am on any given day. As is clear from comparison between FIG. 9 and FIG. 10, since the cooling device is not used in spring and autumn, the power consumption in spring and autumn is less than the power consumption in summer.

  Conventionally, generally, power from a power company with a relatively low price is used for charging the storage battery 5 in the midnight time zone T1. Furthermore, conventionally, charging is performed to the limit of the capacity of the storage battery 5 in the midnight time zone T1, and the electric power stored in the storage battery 5 is the morning time zone T2, the daytime time zone T3, and the night time zone T4. Is consumed. When the electric power stored in the storage battery 5 is used up in the morning time zone T2, the daytime time zone T3, and the night time zone T4, the electric power supplied from the electric power company is used.

  Conventionally, the electric power obtained by solar power generation in the daytime period T3 is supplied to the load 7 or output to the electric power system 6. Output of power to the power grid 6 corresponds to power sale. Furthermore, conventionally, a method has been proposed in which the storage battery 5 is not charged in the late-night time zone T1, but the storage battery 5 is charged in the daytime time zone T3.

  On the other hand, the power control apparatus 1 according to the embodiment grasps a necessary amount of power, and causes the storage battery 5 to store only the amount of power that is scheduled to be consumed. Therefore, compared with the past, the time when the remaining amount of power stored in the storage battery 5 of the embodiment becomes the upper limit of the capacity is short.

  FIG. 11 is a diagram illustrating an example of the transition of the capacity of power stored in the storage battery 5 according to the related art and the embodiment on a summer weekday. In FIG. 11, the upper limit of the capacity of power stored in the storage battery 5 is 6 kWh. At the time of charging, electric power is stored in the storage battery 5 at a rate of 2 kWh per hour. Conventionally, charging is stopped when the capacity of the electric power stored in the storage battery 5 reaches the upper limit of 6 kWh. In contrast, in the embodiment, the power control device 1 stops charging when the capacity of the power stored in the storage battery 5 becomes less than the above upper limit. The amount less than the upper limit is 4 kWh.

  FIG. 12 is a diagram illustrating an example of the transition of the capacity of the electric power stored in the storage battery 5 according to the related art and the embodiment on a summer holiday. As is clear from FIGS. 11 and 12, the remaining amount of power stored in the storage battery 5 of the embodiment does not become the upper limit of the capacity of the storage battery 5. On the summer holiday of the embodiment, the power control device 1 can shorten the time when the remaining amount of power stored in the storage battery 5 becomes zero compared to the conventional case.

  FIG. 13 is a diagram illustrating an example of the transition of the capacity of power stored in the storage battery 5 according to the related art and the embodiment on weekdays in spring and autumn. FIG. 14 is a diagram illustrating an example of the transition of the capacity of power stored in the storage battery 5 according to the related art and the embodiment on spring and autumn holidays. As is clear when comparing FIGS. 13 and 14 with FIGS. 11 and 12, since the cooling device is not used in spring and autumn, there is a state in which the capacity of the electric power stored in the storage battery 5 is relatively large. It lasts relatively long. On the other hand, in the embodiment, a state in which the capacity of the electric power stored in the storage battery 5 is relatively small is maintained.

  In the power control device 1 according to the embodiment, the control unit 15 determines whether or not solar power generation is performed on the control target day, and is specified based on the determination result, the load data 21, and the usage time data. Based on the power consumption for each time zone of the load 7 to be controlled, control is performed to further reduce the amount of power stored in the storage battery 5. That is, the power control device 1 can suppress a state in which the capacity of the power stored in the storage battery 5 is high. In addition, the power control device 1 can store as low-cost power as possible in the storage battery 5.

  Generally, when charging and discharging of the storage battery 5 are repeated, the capacity of electric power that can charge the storage battery 5 decreases. If the capacity eventually decreases to a certain value or less, the storage battery 5 cannot be used. This is because the life is shorter as the remaining amount of the storage battery 5 is larger, as shown in FIG. FIG. 15 is a diagram showing a life characteristic X of the storage battery showing a relationship between the ratio of the remaining capacity of the storage battery and the ratio of deterioration of the storage battery. The rate of deterioration of the storage battery in FIG. 15 is a rate assuming that the rate when power is not stored in the storage battery is 100%. In FIG. 15, a relatively large percentage value of the deterioration rate of the storage battery means that the deterioration of the storage battery is relatively small and the life of the storage battery is relatively long. The power control device 1 performs control to reduce the capacity of power stored in the storage battery 5 as much as possible. That is, the power control device 1 can control charging and discharging of the storage battery 5 while suppressing deterioration of the storage battery 5.

  Reducing the capacity of power stored in the storage battery 5 means that the power control device 1 decreases the amount of power that charges the storage battery 5. When the power control device 1 charges the storage battery 5, the DC voltage conversion circuit 12 converts the voltage of the DC power obtained by the solar panel 3 to generate power based on sunlight into a constant voltage, and the storage battery The charging / discharging circuit 13 converts the electric power obtained by the DC voltage conversion circuit 12 into a voltage suitable for charging the storage battery 5 and then stores it in the storage battery 5. Alternatively, the DC / AC conversion circuit 14 converts AC power from the power system 6 into DC power, and the storage battery charging / discharging circuit 13 converts the DC power from the DC / AC conversion circuit 14 into a voltage suitable for charging the storage battery 5. To store in the storage battery 5.

  When the storage battery 5 stores electric power, some of the circuits included in the DC voltage conversion circuit 12, the storage battery charging / discharging circuit 13, and the DC / AC conversion circuit 14 perform an on / off operation. Occurs. Decreasing the capacity of the electric power stored in the storage battery 5 can reduce the number of times the above circuit performs the on and off operations, thereby suppressing energy loss. In addition, reducing the capacity of the electric power stored in the storage battery 5 can suppress deterioration of a circuit that performs on and off operations.

  Generally, since the temperature range in which the storage battery 5 can be used is determined, it is necessary to keep the temperature inside the power conversion circuit 11 below a predetermined temperature. When energy is lost, heat is generated, and the heat raises the temperature inside the power conversion circuit 11 of the power control device 1, but by reducing the capacity of the power stored in the storage battery 5, the power conversion circuit 11. It is possible to suppress an increase in the temperature inside. By suppressing the temperature inside the power conversion circuit 11 from rising, it is possible to suppress deterioration and malfunction of electronic components that deteriorate or malfunction when the temperature rises. The electronic component is a component included in the power conversion circuit 11.

  In the description using FIGS. 6, 7, 8, 11, 12, 13, and 14, the power control device 1 is configured to store the storage battery 5 until the capacity of the power stored in the storage battery 5 becomes zero during discharging. To discharge. However, the power control device 1 may stop the discharge from the storage battery 5 before the capacity of the power stored in the storage battery 5 becomes zero at the time of discharging. That is, the control unit 15 may control the charging and discharging of the storage battery 5 without reducing the amount of power stored in the storage battery 5 below a predetermined amount. Thereby, the power control apparatus 1 can cope with the case where the supply of power from the power system 6 stops suddenly. An example of the case where the supply of power from the power system 6 suddenly stops is when a disaster occurs.

  The power control apparatus 1 according to the embodiment reduces the amount of power stored in the storage battery 5 as much as possible. Thereby, if the charging time is constant, the current used for charging per unit time can be suppressed. By suppressing the current used for charging per unit time, the contract power of the user can be lowered.

  FIG. 16 is a diagram illustrating the processing circuit 31 when at least a part of the components configuring the control unit 15 included in the power control apparatus 1 according to the embodiment is realized by the processing circuit 31. That is, at least a part of the function of the control unit 15 may be realized by the processing circuit 31.

  The processing circuit 31 is dedicated hardware. The processing circuit 31 is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination thereof. It is. A part of the control unit 15 may be dedicated hardware separate from the remaining part.

  FIG. 17 is a diagram illustrating the processor 41 when at least a part of the functions of the control unit 15 included in the power control apparatus 1 according to the embodiment is realized by the processor 41. That is, at least a part of the functions of the control unit 15 may be realized by the processor 41 that executes a program stored in the memory 42. The processor 41 is a CPU (Central Processing Unit), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor). FIG. 17 also shows the memory 42.

  When at least a part of the functions of the control unit 15 is realized by the processor 41, the part of the functions is realized by a combination of the processor 41 and software, firmware, or software and firmware. Software or firmware is described as a program and stored in the memory 42. The processor 41 implements at least a part of the functions of the control unit 15 by reading and executing a program stored in the memory 42.

  That is, when at least a part of the functions of the control unit 15 is realized by the processor 41, the power control device 1 executes a program that results in the execution of the steps executed by at least a part of the control unit 15. It has a memory 42 for storing. It can be said that the program stored in the memory 42 causes the computer to execute a procedure or method executed by at least a part of the control unit 15.

  The memory 42 is, for example, a nonvolatile or volatile memory such as a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, an EPROM (Erasable Programmable Read Only Memory), or an EEPROM (Electrically Erasable Programmable Read-Only Memory). A semiconductor memory, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, a DVD (Digital Versatile Disk), or the like.

  Regarding the plurality of functions of the control unit 15, a part of the plurality of functions may be realized by dedicated hardware, and the remaining part of the plurality of functions may be realized by software or firmware. Thus, the plurality of functions of the control unit 15 can be realized by hardware, software, firmware, or a combination thereof.

  The house 2 in the embodiment described above may be replaced with a building other than the house 2. In that case, the user is a person who uses the building.

  The configuration described in the above embodiment shows an example of the contents of the present invention, and can be combined with another known technique, and can be combined with other configurations without departing from the gist of the present invention. It is also possible to omit or change the part.

  DESCRIPTION OF SYMBOLS 1 Power control apparatus, 2 House, 3 Solar panel, 4 Solar module, 5 Storage battery, 6 Electric power system, 7 Load, 8 Operation terminal device, 9 Internet, 11 Power conversion circuit, 12 DC voltage conversion circuit, 13 Storage battery charge Discharge circuit, 14 DC / AC conversion circuit, 15 control unit, 16 storage unit, 17 sensor, 21 load data, 22 season data, 23 use day time data, 24 user data, 25 weather data, 31 processing circuit, 41 processor, 42 Memory.

Claims (6)

A power control device that controls charging and discharging of a storage battery,
A DC voltage conversion circuit that converts a voltage of DC power obtained by a solar module having a solar panel that generates power based on sunlight into a constant voltage;
A storage battery charging / discharging circuit for storing the DC power obtained by the DC voltage conversion circuit in the storage battery;
A DC / AC converter circuit that converts AC power from the power system into DC power;
The weather forecast data for the day of the storage battery charging and discharging control target, the load data indicating the power consumption of the load that operates using power, and the load for each time zone on the control target day A storage unit for storing usage time data indicating a used time;
A controller for controlling the DC voltage conversion circuit, the storage battery charging / discharging circuit, and the DC / AC conversion circuit based on the weather forecast data, the load data, and the usage time data stored in the storage unit; ,
The storage battery charging / discharging circuit has a function of discharging the storage battery,
The control unit performs control for allocating the power discharged from the storage battery to the power consumed by the load, and whether or not solar power generation is performed on the control target day based on the weather forecast data. The amount of power stored in the storage battery is reduced based on the determination result and the power consumption for each load time zone specified based on the load data and the usage time data. A power control apparatus characterized by performing control to perform. The power control apparatus according to claim 1, wherein the control unit calculates a power consumption amount of the load based on the load data and the usage time data. The power control apparatus according to claim 1 or 2, wherein the weather forecast data, the load data, and the usage time data stored in the storage unit are data obtained from the Internet. The said control part controls charge and discharge of the said storage battery, without making the quantity of the electric power which the said storage battery has stored less than the predetermined quantity. The any one of Claim 1 to 3 characterized by the above-mentioned. The power control apparatus described. The controller is
When it is determined that solar power generation is performed on the control target day, the amount of electric power obtained by the solar module is started on the control target day. It is determined whether or not the power consumption of the load in 24 hours after the
When it is determined that the amount of power obtained by the solar module is equal to or greater than the power consumption amount of the load in the 24 hours, the solar power generation on the day of the control is performed during the 24 hours. The solar power generation stores a part of the power obtained by the solar module while storing the power of the amount of power corresponding to the power consumption of the load after the solar power generation is completed in the storage battery. Assigned to the power consumed by the load in the time zone to be performed, in the time zone after the end of the solar power generation on the day of the control, to discharge the storage battery, the power released from the storage battery The power control apparatus according to any one of claims 1 to 3, wherein control is performed to allocate power consumed by a load. When the control unit determines that solar power generation is not performed on the day of the control,
In the late-night time zone of the day to be controlled,
For the DC / AC conversion circuit, at least part of the AC power from the power system is converted to DC power,
Assigning a portion of the AC power to the power consumed by the load;
When the power consumption of the load in a time zone other than the midnight time zone of the control target day is equal to or less than the chargeable power amount that can be stored in the storage battery in the midnight time zone, the midnight time Storing the power of the power consumption of the load in a time zone other than the belt in the storage battery,
When the power consumption of the load in a time zone other than the midnight time zone is greater than the chargeable power amount, the power up to the limit of the storage battery or the power of the chargeable power amount is stored in the storage battery,
The control is performed by causing the storage battery to discharge in a time zone other than the midnight time zone of the control target day and assigning the power discharged from the storage battery to the power consumed by the load. The power control device according to any one of 1, 2, 3, and 5.

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