JP5690618B2 - Battery charge control system - Google Patents

Description

  The present invention relates to a storage battery charge control system that can charge a storage battery without disturbing the operation of a home device.

  Solar power generators and wind power generators have been widely put into practical use as power sources using renewable energy. In addition, fuel cells using clean energy have been put into practical use as next-generation private power generation power supply devices. The electric power supplied by these private power generation devices is consumed by the home appliances, and the surplus is stored in the storage battery. Furthermore, a part is sent out to the power transmission / distribution electric wire side for electric power sale.

JP 2010-88276 A

The known prior art has the following problems to be solved.
The electric power generated by the private power generator is supplied to the home wiring and used. A part of it is sent to the power transmission and distribution line side for power sales. Furthermore, the storage battery is charged with surplus power and used at night. On the other hand, when the power generation capacity of the private power generation device is low, the storage battery is charged by receiving nighttime power from the transmission and distribution lines. This power is used in the daytime. Here, when the night battery is charged to the storage battery, the storage battery operates as a load on the power supply, like other power devices. That is, a load current flows from the power source toward the storage battery.

  If the heater or the water heater is operated while charging the storage battery in this way, the contracted power capacity may be exceeded. In particular, due to the characteristics of the storage battery, a large charging current flows at the start of charging, and the charging current decreases at the end of charging. Thereby, use of another electric power apparatus may be prevented and a breaker may be operated. If the charging current is set sufficiently low, this problem does not occur, but the charging time becomes long.

  An object of this invention is to provide the storage battery charge control system which can charge a storage battery appropriately, without preventing use of another electric power apparatus.

The following configurations are means for solving the above-described problems.
<Configuration 1>
Drives the home equipment in commercial electric power supplied from the TD line, a system for charging the storage battery with the commercial power during use this home device monitors the power received from the TD line, the home When the load current measuring means for measuring the load current supplied to the device and the measured load current and the charging current of the storage battery are added, the maximum allowable load current obtained from the contract power capacity related to the received power is not exceeded. Charging current calculation means for calculating the appropriate charging current of the storage battery, and charging the storage battery with the appropriate charging current, and whenever the measured load current changes by a certain amount or more, the appropriate charging current of the storage battery A storage battery charge control system comprising: a storage battery charge control means for recalculating the storage battery and changing the charge current of the storage battery

<Configuration 2>
A system that supplies electric power supplied from a private power generator to the home appliance and charges the storage battery with surplus power, and monitors the power generated by the private power generator and measures the load current supplied to the home appliance Charging for calculating an appropriate charging current for the storage battery within a range not exceeding the maximum operating current corresponding to the generated power of the private power generation power supply when the current measuring means and the measured load current and the charging current of the storage battery are added The current calculation means and the storage battery are charged with the appropriate charging current, and the storage battery charging current is recalculated each time the measured load current and the generated power of the private power generation apparatus change by a certain amount or more. And a storage battery charging control system for changing a charging current of the storage battery.

<Configuration 3>
In the storage battery charging control system according to Configuration 1, the charging current calculation means sets the load current as IL, the charging current of the storage battery as IB, a maximum allowable load current as IA, and IA− (IL + IB) as a load current. The reserve current IR of the storage battery is set so that the reserve current IR of the load current is equal to or greater than the load current of the power device through which the maximum load current flows when activated alone. Storage battery charge control system.

<Configuration 4>
In the storage battery charging control system according to Configuration 2, when the load current is IL, the storage battery charging current is IB, the maximum operating current is IGA, and IGA- (IL + IB) is a reserve IR of the load current The storage battery charging control system is characterized in that the charging current of the storage battery is set so that the reserve current IR of the load current becomes equal to or greater than the load current of the power device through which the maximum load current flows when the stand-alone IR is activated.

<Configuration 5>
The storage battery charge control system according to any one of configurations 1 to 4, wherein the storage battery charge control means includes: a load current supplied to the home appliance; and a charge end time of the storage battery when charged with the appropriate charge current. A storage battery charging control system characterized by displaying on a display.

<Configuration 6>
In the storage battery charging control system according to any one of the configurations 1 to 5, when charging of the storage battery is started from the private power generation power supply device using the first charging circuit, and charging is interrupted, wait until a designated time. A storage battery charge control system characterized by controlling charging to resume.

<Configuration 7>
In the storage battery charging control system according to any one of the configurations 1 to 6, when charging of the storage battery is started from the transmission / distribution electric line using the second charging circuit and charging is interrupted, the charging is waited until a specified time. The storage battery charging control system is characterized in that control is performed so as to resume the operation.

<Configuration 8>
In the storage battery charging control system according to any one of configurations 1 to 7, the usage state of the household device is monitored, and the household device is automatically turned on and off according to a preset energy usage standard to control the amount of energy used. A storage battery charge is provided, wherein when the HEMS management server automatically turns on any of the in-home devices, the storage battery charging control means temporarily stops the charging of the storage battery. Control system.

<Configuration 9>
In the storage battery charge control system according to any one of configurations 1 to 8, when there are a plurality of storage batteries to be charged, the storage battery charge control means sets a start time and a charge end time of each storage battery in terms of time. The storage battery charging control system is characterized in that the total value of the load current of the home appliance and the charging current of the storage battery is controlled within an appropriate range.

<Effect of Configuration 1>
By calculating the appropriate charging current of the storage battery within a range that does not exceed the maximum allowable load current obtained from the contract power capacity, the storage battery can be efficiently charged within the allowable range.
<Effect of Configuration 2>
When the power generated by the private power generation device changes, the appropriate maximum operating current also changes. The measured value of the load current and the generated power of the private power generation apparatus can be measured continuously in time, and the appropriate charging current of the storage battery can be calculated and followed.
<Effect of Configuration 3>
There is no worry that the breaker will be activated even if a power device with a maximum load current is activated while charging the storage battery.
<Effect of Configuration 4>
There is no worry that the breaker will be activated even if a power device with a maximum load current is activated while charging the storage battery.
<Effect of Configuration 5>
When you want to finish charging the storage battery quickly, you can look at the display and turn off some of the home devices to save power.
<Effect of Configuration 6>
Due to the influence of home appliances, the self-generated power supply device cannot be fully charged, and charging may be interrupted. At this time, if a cheap nighttime power transmission start time is designated, charging can be resumed from that time.
<Effect of Configuration 7>
Due to the influence of home appliances, the self-generated power supply device cannot be fully charged, and charging may be interrupted. At this time, if a cheap nighttime power transmission start time is designated, charging can be resumed from that time.
<Effect of Configuration 8>
A home energy management system (HEMS) management server may automatically turn on and off an air conditioner, for example. Since an air conditioner requires a large current at startup, there is a possibility that a load current exceeding the allowable value temporarily flows. There is no problem even if the storage battery is cut off freely. Therefore, the charging of the storage battery is temporarily stopped when such a home device is activated.
<Effect of Configuration 9>
When there are a plurality of storage batteries to be charged, the charging current can be leveled by shifting the timing of charging without simultaneously charging.

It is a block diagram which shows the storage battery charge control system of Example 1. It is explanatory drawing which shows the example of the data used for a calculation process. It is explanatory drawing of charge control. It is explanatory drawing of the charge control different from FIG. It is a storage battery monitor screen explanatory drawing displayed on the display. It is storage battery monitor screen explanatory drawing in case there exist a some storage battery. It is a charge control circuit for a plurality of storage batteries. It is a charge control circuit in the state where the storage battery is connected to a circuit separated by a plurality of breakers.

  In general, when commercial power is used, a contract power capacity is defined for received power. The power used by the home equipment is used so as not to exceed the contracted power capacity. Usually, it refers to the breaking current of the breaker and is called 40 amp contract or 50 amp contract. Here, for example, when a large-capacity storage battery such as that used in an electric vehicle is rapidly charged while using various home appliances, there is a possibility that a large current flows and exceeds the contracted power capacity.

  On the other hand, unlike ordinary home appliances, a storage battery is characterized in that it can be charged without any problems even if the charging current fluctuates temporarily or is intermittent. In the present invention, this feature is used to dynamically control the charging current of the storage battery according to the state of other in-home devices. Furthermore, while performing such control, it is also possible to suspend or resume charging for a time that can be charged at low cost. Hereinafter, embodiments of the present invention will be described in detail for each example.

FIG. 1 is a block diagram illustrating a storage battery charge control system 10 according to the first embodiment.
The illustrated system 10 is installed in a building such as a general household. In this building, commercial power is supplied from the transmission / distribution line 14 to the home wiring 15 via the distribution board 16. In addition, a private power generation power supply 24 is provided in this building. Further, a storage battery 26 is provided for storing electric power used inside the building. The storage battery of the electric vehicle 27 can also be connected to the location of the storage battery in this figure.

  In order to charge the storage battery 26 with electric power, a first charging circuit 28 and a second charging circuit 30 are provided. In addition, a discharge circuit 32 is provided to supply power from the storage battery 26 to the home wiring 15 side. In order to selectively connect the storage battery 26 to any one of the first charging circuit 28, the second charging circuit 30, and the discharging circuit 32, a switch circuit 33 is provided.

  Further, a well-known power conditioner 18 is provided in order to control the sale of surplus power from the private power generation device 24. Further, a well-known smart meter 20 is provided for measuring the load current flowing through the home wiring 15 and allowing the electric power company to read the integrated power remotely. First, a specific configuration of each part will be described for the above part.

[In-house power generator]
For the charging of the storage battery 26, electric power supplied from the private power generation power supply device 24 and the transmission and distribution line 14 is used. The private power generation device 24 is a solar power generation device that converts solar energy into electrical energy and outputs it, a wind power generation device that converts wind energy into electrical energy and outputs it, and a fuel that generates electricity using hydrogen or the like as fuel. Batteries are well known. In addition to this, there is also known a power supply device that converts thermal energy and hydraulic wave power into electric energy and outputs the electric energy. All of these can be used as private power generators in the system of the present invention.

[Transmission and distribution line and home wiring]
The transmission and distribution line 14 is a line for supplying commercial power from an electric power company. The in-home wiring 15 is connected to the transmission / distribution line 14 via the distribution board 16. The in-home wiring 15 is a power distribution facility that is separated by a power receiving facility such as the power transmission / distribution line 14 and the distribution board 16 and supplies power for driving the home equipment 22 installed in a house, a condominium, or the like. The distribution board 16 is a device having a built-in branch circuit or breaker for in-house power distribution.

[Storage battery]
The storage battery 26 is a secondary battery having a function of storing and discharging electric power by charging and discharging. The storage battery 26 is used for storing electric power supplied from the private power generation power supply device 24. A storage battery of any battery-powered equipment such as an electric vehicle is also a target for charging by this system. Using the switch circuit 33 shown in the figure, charging is controlled by simultaneously connecting or selectively connecting a plurality of storage batteries to the first charging circuit 28 and the second charging circuit 30.

  Note that the output of the private power generation device 24 may be supplied directly to the in-home wiring 15 through the power conditioner 18 or may be stored in the storage battery 26 and then used through the discharge circuit 32. The storage battery 26 is also used for storing electric power supplied from the transmission / distribution electric line 12, and can store cheap nighttime electric power.

[Charge / discharge circuit]
The following circuits are provided for charging and discharging the storage battery 26.
The first charging circuit 28 is a circuit that accepts the electric power of the private power generation power supply 24 and outputs the requested DC power to charge the storage battery 26. The second charging circuit 30 is a circuit that receives the power of the home wiring 15 and outputs the requested DC power to charge the storage battery 26. The discharge circuit 32 is a circuit that receives the power of the storage battery 26, outputs the requested AC power, and supplies it to the home wiring 15.

  The first charging circuit 28 includes, for example, a DC-DC converter that converts a DC voltage output from the photovoltaic power generator into a voltage suitable for charging the storage battery 26, a current control circuit that controls the charging current, and a charging time. It has a timer to control. The second charging circuit 30 is, for example, connected to the AC 100 volt home wiring 15 and converted into a DC voltage suitable for charging the storage battery 26, a current control circuit for controlling the charging current, and a charging time. A timer for controlling the operation is provided. The discharge circuit 32 includes a DC-AC converter that connects to the storage battery 26 and outputs an AC voltage for the home wiring 15, an overcurrent protection circuit, and the like.

[Discharge control of storage battery]
The system shown in FIG. 1 may be controlled by a HEMS (Home Energy Management Service) management server 34, for example. The HEMS management server 34 monitors the energy supply amount and the energy consumption amount in the building such as a general house in detail, displays the result on the display 40, or controls the operation of the air conditioner, for example, to set the proper temperature. It has a function to control it. In this embodiment, a charge control function for the storage battery 26 is provided to the HEMS management server 34. The same control can be performed even if a computer dedicated to charge control of the storage battery 26 is used.

  The HEMS management server 34 illustrated in FIG. 1 is a known computer, and includes an arithmetic processing device 36 and a storage device 38. The display 40 for displaying the calculation processing result can also serve as an interface for data input by a touch panel, for example.

  Each means shown in the arithmetic processing unit 36 is a functional block that functions by a computer program. A HEMS control means 42, a load current measurement means 44, a charge current calculation means 46, and a storage battery charge control means 48 are provided. The storage device 38 stores various data as illustrated in FIG. 2 for arithmetic processing. These are collectively displayed as HEMS management data 50 in FIG.

  The load current measuring unit 44 has a function of monitoring the received power from the transmission / distribution electric line 14 through the smart meter 20 and measuring the load current IL supplied to the home appliance 22. The charging current calculation means 46 adds the measured load current IL and the charging current IB of the storage battery 26, and the storage battery 26 does not exceed the maximum allowable load current IA determined from the contract power capacity PK related to the received power PT. Has a function of calculating the appropriate charging current IBB.

  The storage battery charge control means 48 charges the storage battery 26 with the appropriate charging current IBB, and recalculates the appropriate charging current IBB of the storage battery 26 every time the measured load current IL changes by a certain amount IC. It has a function to change the charging current. The actual charging current may be equal to or less than the appropriate charging current IBB obtained by calculation. In practice, when it is detected that the load current IL has changed by a certain amount IC or more, the appropriate charging current IBB of the storage battery 26 may be recalculated, and the detection timing of the load current IL is arbitrary.

FIG. 2 is an explanatory diagram showing an example of data used for the above arithmetic processing.
The illustrated data 50 to 78 are stored in the storage device 38 shown in FIG. The HEMS management data 50 is data used for well-known HEMS management and is not related to the present invention, so the description is omitted. Since the data 52 to 70 are indicated by alphabets, numerals in the description are omitted.

  In the present invention, the charging current IB is supplied to the storage battery 26 within an allowable range so as not to prevent the use of the home appliance 22. For example, the maximum allowable load current IA may be set to 50A in a 50A contract. Further, as will be described later, a maximum allowable load current IA may be set for each room that supplies power through a single breaker, and the charging current IB of the storage battery charged in that room may be controlled. Therefore, the maximum allowable load current IA is arbitrarily set under the limit of the contract power capacity PK.

  Moreover, when charging the storage battery 26 using the private power generation power supply 24, the generated power PG of the private power generation power supply 24 becomes a problem. In the case of a photovoltaic power generator, it is preferable to operate within the range of operating current at the optimum operating point. The operating current at this optimum operating point was expressed as the maximum operating current IGA. The maximum operating current IGA may be arbitrarily set in consideration of the characteristics of the private power generator 24. Each data is used by substituting it into the arithmetic expression shown on the right side of FIG.

  In many cases, the capacity of the power receiving facility or the electric device is displayed as electric power. However, since the power receiving voltage of the commercial power source is constant, the calculation should be performed by paying attention to the current value. When there are two systems of 100 volt and 200 volt home wiring, it is preferable to calculate the current value by converting to 100 volt, for example.

  When the private power generation device 24 is a solar power generation device, a direct current is output, so the charging current IB of the storage battery 26 may be calculated with a direct current value. While the storage battery 26 is being charged, power is supplied from the private power generation power supply 24 to the in-home device 22 via the DC / AC converter inside the power conditioner 18. At this time, it is preferable to use the DC input current value of the DC / AC converter as the load current IL of the home appliance 22. Further, when charging various storage batteries such as an electric vehicle, the storage battery characteristic data 79 may be stored in the storage device 38 in advance. Thereby, the charge control which considered the charging current characteristic etc. of the storage battery 26 can be performed. The specific contents of each data will be described in the explanation of the operation.

FIG. 3 is an explanatory diagram of charging control.
The horizontal axis of the figure shows the passage of time for one day. The vertical axis represents the current value, and the thick solid line represents the time change of the load current IL of the home appliance 22. The load current IL is, for example, the total value of the load currents of all the in-home devices 22 connected to the in-home wiring 15, and an average value for each hour is displayed. The straight line of the uppermost alternate long and short dash line is the maximum allowable load current IA obtained from the contract power capacity PK.

  The charging current calculation means 46 (FIG. 1) assumes that the load current is IL, the charging current of the storage battery 26 is IB, and the maximum allowable load current is IA, then IA− (IL + IB) becomes a reserve IR of the load current. To control. That is, the appropriate charging current IBB of the storage battery 26 is calculated in a range where (IL + IB) does not exceed (IA−IR). The IR is for giving a margin so as not to prevent the use of the other in-home equipment 22, and for example, the maximum allowable load current may be set to 10% of IA.

  Further, among all the home devices 22 connected to the home wiring 15, the load current of the home device 22 through which the maximum load current flows when activated alone may be obtained and set to IR. As a result, the breaker does not operate no matter which home device 22 is activated by the user during charging of the storage battery. As described above, for example, the load current IL is measured every hour, and the appropriate charging current IBB is calculated and changed to an appropriate charging current each time. Thus, the charging current dynamically changes with time as indicated by the broken line in FIG. The one-dot chain line immediately below the one-dot chain line indicating the maximum allowable load current IA indicates (IL + IB). If a charging current less than this is selected, the storage battery 26 can be efficiently charged within the allowable range.

FIG. 4 is an explanatory diagram of another charge control.
The format of the graph of FIG. 4 is the same as that of FIG. In this embodiment, when the load current IL of the home appliance 22 changes by a certain value IC or more (for example, 10 amperes or more), control is performed so as to change the charging current IB of the storage battery. The calculation method of the current value at that time may be the same as the example of FIG. When the load current IL of the home device 22 exceeds a threshold value (for example, 80% of the maximum allowable load current IA), the charging current IB is automatically cut off.

  As can be seen from FIG. 3 and FIG. 4, charging with a relatively large current is possible during a time period in which midnight power can be received from the transmission / distribution line. On the other hand, when the storage battery 26 is charged using the private power generation power supply 24 in the daytime, fine control is required. If the charging completion time of the storage battery to be charged is not specified, it is possible to perform control such that charging is performed with a small current, for example, charging is performed from the private power generation power supply 24 during the daytime, and the rest is charged with midnight power.

  In this case, charging of the storage battery is started using the private power generation power supply 24, and when charging is interrupted, control is performed so that charging is resumed after waiting for a designated time. It is recommended to designate the start of inexpensive nighttime power transmission as the charging resumption time. Conversely, even if charging is started using inexpensive nighttime power, charging is interrupted when the nighttime power transmission time has passed without charging being completed. And it is good to restart charge at the time when the private power generation device 24 operates.

FIG. 5 is an explanatory diagram of a storage battery monitor screen displayed on the display.
If the screen as shown in the figure is displayed on the display 40 (FIG. 1), the user can simultaneously monitor the usage status of the home appliance 22 and the charging status of the storage battery 26. The band graph in the figure represents the power consumption of the in-home device 22 currently used in a horizontal width and is color-coded. Thus, the user can understand how much power is consumed by which device.

  In this state, the current charge amount of the storage battery 26 is displayed in two colors. This example shows that about 50% charging is complete. On the right side of the icon of the storage battery, the charging end time when charging is continued with the current charging current is displayed. If it is found that the smaller the total amount of power used by the other home devices 22 is, the shorter the time until the end of charging is, the user is conscious of power saving.

  Further, the HEMS management server 34 illustrated in FIG. 1 may automatically turn on / off an air conditioner, for example. Since an air conditioner requires a large current at startup, there is a possibility that a load current exceeding the allowable value temporarily flows. There is no harmful effect even if charging of the storage battery 26 is interrupted freely. Therefore, when the HEMS management server 34 automatically turns on any of the in-home devices 22, the storage battery charge control means 48 may suspend charging of the storage battery 26. This temporary stop time may be about one minute, for example.

  Further, a desired time for completing the charging of the storage battery 26 can be set in the HEMS management server 34 using a screen as shown in FIG. The HEMS management server supplies the maximum charging current in a range where the total value of the load current including the amount of other power devices from the charging start time to the charging end time does not exceed the allowable value. Conversely, if there is a sufficient margin, it is better to charge for a long time with a low charging current.

FIG. 6 is an explanatory diagram of a storage battery monitor screen when there are a plurality of storage batteries.
For example, there may be a case where charging is requested simultaneously for both a private power generation power supply 24 inside a building and a storage battery for low-cost nighttime power and a storage battery for an electric vehicle. For example, there may be a case where a separate storage battery is installed for each room inside the building. In this case, if charging is performed in parallel, the charging current increases, and the use of other in-home devices 22 is restricted.

  Therefore, for example, the charging priority of each storage battery and the designation data of the charging end time are input to the storage battery characteristic data 79 shown in FIG. As shown in FIG. 6, the storage battery charge control means 48 displays an icon of a storage battery to be charged. Below the icon, a symbol for identifying the storage battery (storage battery 01 and the like), a charging start time 76 and a charging end time 78 of each storage battery 26 are displayed. The colored portion of the icon indicates the charge amount ratio. The two on the left are fully charged, the third is 50% charged and the right is uncharged.

  In this way, the storage battery charge control means 48 shifts the charging start time 76 and the charging end time 78 of each storage battery 26 with respect to each other in time, so that the sum of the load current of the home appliance 22 and the charging current of the storage battery 26 is obtained. Control the value to an appropriate range. That is, when there are a plurality of storage batteries to be charged, the charging current can be leveled by shifting the charging timing in order of priority, for example, without charging at the same time.

FIG. 7 shows a charge control circuit for a plurality of storage batteries.
As shown in the figure, for example, when charging of four storage batteries 26 is required, each storage battery 26 is connected to the feeder line 80 via the switch 82. It is assumed that a charging current is supplied from the feeder line 80. In this circuit, the storage battery charging control means 48 alternately turns on and off the switches 82 to charge each storage battery 26. When there is a priority for charging or when no storage battery 26 is designated for the charging end time, for example, control is performed so that charging is performed in order from the left end. When charging of the single battery is completed, control is performed such that the next battery is charged.

  In some cases, it is desirable to end charging of all storage batteries at approximately the same time. For example, there is a case where there are uses in which a plurality of storage batteries are connected in parallel. At this time, for example, it may be controlled to charge each storage battery approximately every 10 minutes to switch the connection and to alternately charge at short intervals. When the charging current is different each time, it is preferable to control charging alternately so that the product of the charging current and the charging time becomes constant.

FIG. 8 shows a charge control circuit in a state where the storage battery is connected to a circuit separated by a plurality of breakers.
As shown in this figure, a plurality of storage batteries are arranged in different rooms, for example, and may be connected to the home wiring 15 via different breakers 84, respectively. A storage battery of an electric vehicle parked in the garage is also connected to this circuit. In such a case, the operating current of each breaker 84 may be controlled as the maximum allowable load current IA. In addition to this control, the load current supplied to all in-house devices 22 in the building is measured at the location of the distribution board 16 shown in FIG.

DESCRIPTION OF SYMBOLS 10 Storage battery charge control system 14 Transmission / distribution electric wire path 15 In-home wiring 16 Distribution board 18 Power conditioner 20 Smart meter 22 In-home equipment 24 Private power generation power supply device 26 Storage battery 27 Electric vehicle 28 1st charging circuit 30 2nd charging circuit 32 Discharging circuit 33 Switch circuit 34 HEMS management server 36 Arithmetic processor 38 Storage device 40 Display 42 HEMS control means 44 Load current measurement means 46 Charging current calculation means 48 Storage battery charge control means 50 HEMS management data 52 Received power PT
54 Load current IL
56 Charging current IB
58 Contracted power capacity PK
60 Maximum allowable load current IA
62 Load current reserve IR
64 Appropriate charging current IBB
66 Power generation PG
68 Maximum operating current IGA
70 constant value IC
72 Energy Use Standard 76 Charging Start Time 78 Charging End Time 79 Storage Battery Characteristic Data 80 Feed Line 82 Switch 84 Breaker

Claims (9)

A system that drives household equipment with commercial power supplied from a transmission and distribution line and charges a storage battery with commercial power while using the household equipment,
Monitor the power received from the TD line, and the load current measuring means for measuring a load current supplied to the customer premises equipment,
Charging current calculation means for calculating an appropriate charging current for the storage battery within a range not exceeding a maximum allowable load current obtained from a contract power capacity related to the received power when the measured load current and the charging current of the storage battery are added When,
Storage battery charge control means for charging the storage battery with an appropriate charging current and recalculating the appropriate charging current of the storage battery every time the measured load current changes by a certain amount or more to change the charging current of the storage battery. And a storage battery charge control system. A system for supplying electric power supplied from a private power generation power supply device to a household device and charging a storage battery with surplus power,
Load current measuring means for monitoring the generated power of the private power generation power supply device and measuring the load current supplied from the private power generation power supply device to the in-home equipment ;
When the measured load current and the charging current of the storage battery are added, charging current calculation means for calculating the appropriate charging current of the storage battery within a range not exceeding the maximum operating current corresponding to the generated power of the private power generation power supply device;
The storage battery is charged with the appropriate charging current, and whenever the measured load current and the generated power of the private power generation device change by a certain amount or more, the charge current of the storage battery is recalculated, A storage battery charge control system comprising storage battery charge control means for changing a charge current. In the storage battery charging control system according to claim 1,
The charging current calculation means includes
When the load current is IL, the charging current of the storage battery is IB, the maximum allowable load current is IA, and IA− (IL + IB) is a reserve IR of the load current,
A storage battery charging control system, wherein the charging current of the storage battery is set such that a reserve IR of the load current is equal to or greater than a load current of a power device through which a maximum load current flows when the stand-alone IR is activated. In the storage battery charging control system according to claim 2,
When the load current is IL, the charging current of the storage battery is IB, the maximum operating current is IGA, and IGA- (IL + IB) is a reserve IR of the load current,
A storage battery charging control system, wherein the charging current of the storage battery is set such that a reserve IR of the load current is equal to or greater than a load current of a power device through which a maximum load current flows when the stand-alone IR is activated. In the storage battery charge control system according to any one of claims 1 to 4,
The storage battery charge control means includes
A storage battery charging control system, wherein a load current supplied to the home appliance and a charging end time of the storage battery when charged with the appropriate charging current are displayed on a display. In the storage battery charging control system according to any one of claims 1 to 5,
Storage battery charge control characterized in that charging of a storage battery is started from a private power generation device using a first charging circuit, and when charging is interrupted, control is performed so that charging is resumed after waiting for a specified time. system. In the storage battery charging control system according to any one of claims 1 to 6,
A storage battery charging control system characterized by starting charging of a storage battery from a power transmission / distribution line using a second charging circuit, and controlling charging to resume after waiting until a specified time when charging is interrupted . In the storage battery charging control system according to any one of claims 1 to 7,
There is provided a HEMS management server that monitors the usage state of the home appliance, automatically turns on / off the home appliance according to a preset energy usage standard, and controls the amount of energy used. The storage battery charge control means temporarily stops charging the storage battery when automatically turning on the home appliance. In the storage battery charging control system according to any one of claims 1 to 8,
The storage battery charge control means includes
When there are multiple storage batteries to be charged, the charging start time and the charging end time of each storage battery are shifted in time, so that the total value of the load current of the home appliance and the charging current of the storage battery is within an appropriate range. A storage battery charge control system characterized by controlling.

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