JP2012130126A - Power supply control device and power supply system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply control device and a power supply system using the same capable of leveling user's electric power demand.SOLUTION: In a power supply control device and a power supply system, a power measurement part 15 measures an input power to be supplied from a commercial power supply 1 to users. A power control part 14 controls a recharge/discharge of a rechargeable battery 13 and power supply to a load apparatus 12 in response to a control command from a command part 16. The power control part 14 converts AC power supplied from the commercial power supply 1 into DC power to recharge the battery 13 and converts DC power discharged from the battery 13 into AC power to supply the power to the load apparatus 12. When the measurement result of the input power measured with the power measurement part 15 exceeds a prescribed threshold value, the command part 16 outputs a control command for allowing the battery 13 to discharge power to the load apparatus 12 of user's home, and when the measurement result of the input power falls below the threshold value, the command part 16 outputs a control command to recharge the battery 13 by the commercial power 1.

Description

  The present invention relates to a power supply control device and a power supply system using the same.

  In the past, power supply operators have operated power plants in response to changes in power demand so that the grid voltage and frequency of the commercial power supply system supplied to each customer from the power supply operator will not become unstable. The power generation output of the power plant was controlled so that there was no excess or deficiency with respect to the power demand. For example, the power consumption of ordinary households varies greatly depending on the time of day, and there is a tendency for power consumption to increase during meals in the morning and evening and to decrease at night while sleeping. Thus, when the power demand of each consumer fluctuates greatly with time, it is necessary to frequently adjust the power generation output of the power plant so that the amount of power generation follows the change in power demand.

  For example, in the power distribution system described in Patent Document 1, an AC power supply path to which an AC device is connected and a DC power supply path to which a DC device is connected are provided. AC power is supplied from a commercial power source to the AC power supply path, and DC power generated by a DC power generation facility such as a solar power generation device or a fuel cell is supplied to the DC power supply path. Also, in this power distribution system, when the amount of power supplied from the commercial power source to the AC power supply path exceeds a predetermined threshold, the DC power generated by the DC power generation facility is converted into AC and supplied to the AC power supply path. The amount of power supplied from the commercial power source to the AC power supply path is suppressed below the threshold value. In this way, when the power demand for AC equipment increases, the amount of supply from the commercial power supply falls below the threshold by converting the DC power generated by the DC power generation equipment into AC and supplying it to the AC power supply path. It has been suppressed, thereby reducing fluctuations in power demand as seen by the power supplier.

JP 2010-41782 A

  In the above-mentioned power distribution system, although fluctuations in power demand are suppressed in individual consumers, the fluctuations in power demand itself are not lost, so the power supplier again generates power from the power station according to fluctuations in power demand. It was necessary to control the output frequently. Currently, power supply operators operate nuclear power plants, thermal power plants, hydroelectric power plants, etc., and nuclear power plants cannot perform operations that frequently change output power. However, thermal power plants that generate electricity by burning fossil fuels generate soot and carbon dioxide, which has a problem of high environmental impact. In addition, if the output power of the power plant is changed frequently, there is a problem that the power generation equipment is loaded and the life of the power generation equipment is shortened.

  This invention is made | formed in view of the said subject, The place made into the objective provides the power supply control apparatus which can equalize the power demand of a consumer, and a power supply system using the same. It is in.

  In order to solve the above-described problem, the power supply control device of the present invention includes a power acquisition unit, a threshold setting unit, a command unit, and a control unit. The power acquisition unit acquires the measurement result of the input power supplied from the commercial power source to the consumer side. The threshold setting unit sets a threshold for input power. When the measurement result of the input power exceeds the threshold value, the command unit outputs a control command for discharging the storage battery charged with the power supplied from the commercial power source and feeding the load equipment in the consumer, and measuring the input power If the result is less than the threshold, a control command for charging the storage battery with a commercial power supply is output. The control unit controls charging / discharging of the storage battery and power supply to the load device according to a control command from the command unit.

  In this power supply control device, it is also preferable that the threshold value setting unit sets a threshold value for each period, and the command unit outputs a control signal based on a result of comparing the threshold value of each period and the measurement result of the input power.

  In this power supply control device, the threshold setting unit sets a threshold in each time zone of the day, and the command unit sends a control signal based on the result of comparing the threshold value in each time zone and the measurement result of the input power. It is also preferable to output.

  The power supply control device includes a storage unit that stores a measurement result of the input power in a predetermined period, and the threshold setting unit obtains an average value of the input power in the predetermined period based on the measurement result stored in the storage unit. It is also preferable to set this average value as a threshold value.

  The threshold value setting unit obtains the average input power value on the day when the peak value of the input power is maximum within a predetermined period based on the measurement result stored in the storage unit, and sets this input power average value as the threshold value. It is also preferable to do.

  In this power supply control device, a contract capacity determining unit that determines a contract capacity of an electricity bill based on a threshold set by a threshold setting unit, and a contract capacity determined by the contract capacity determining unit are presented to a customer It is also preferable to provide a presentation unit.

  The power supply system of the present invention includes a power measuring unit that measures input power supplied from a commercial power source to a consumer side, and a storage battery that is installed on the consumer side and is charged with power supplied from the commercial power source. And the above power supply control device provided on the consumer side.

  According to the present invention, since the input power from the commercial power supply is controlled to the threshold value, it is possible to provide a power supply control device that leveles the power demand of the consumer.

  In addition, since the input power from the commercial power supply is controlled to the threshold value, it is possible to provide a power supply system that leveles the power demand of consumers.

1 is a schematic system configuration diagram of Embodiment 1. FIG. It is a flowchart explaining operation | movement same as the above. 6 is a schematic system configuration diagram of Embodiment 2. FIG. FIG. 10 is a schematic system configuration diagram of a fifth embodiment. FIG. 10 is a schematic system configuration diagram of a sixth embodiment. FIG. 10 is a schematic system configuration diagram of a seventh embodiment.

  Hereinafter, embodiments of a power supply control device and a power supply system using the power supply control device will be described with reference to the drawings.

(Embodiment 1)
A power supply control device according to Embodiment 1 and a power supply system using the same will be described with reference to FIGS. 1 and 2.

  FIG. 1 is a schematic system configuration diagram of a power supply system. In this power supply system, a commercial power source (for example, AC 100 V) is supplied from a commercial power source 1 to an AC distribution board 11 provided in a consumer 10, and power is supplied to a load device 12 provided in the house via the AC distribution board 11. Is to be supplied. Examples of the load device 12 installed in the customer's home include an air conditioner such as an air conditioner, a television, a lighting device, an acoustic device, and a personal computer.

  Further, the customer 10 is provided with a storage battery 13, a power control unit 14, a power measurement unit 15, a command unit 16, and a threshold setting unit 17.

  The storage battery 13 is provided on the customer 10 side and stores the electric power supplied from the commercial power source 1. The storage battery 13 has a function of detecting storage battery information relating to the state of charge (for example, abnormal information such as the presence or absence of overdischarge or the presence or absence of overcharge), and periodically transmits the storage battery information to the power control unit 14. The storage battery 13 may be installed at least one inside or outside the building of the customer 10.

  When a control command is input from the command unit 16, the power control unit 14 (control unit) refers to the storage battery information from the storage battery 13, and if there is no abnormality in the storage battery 13, charging / discharging of the storage battery 13 according to the content of the control command. Control and control of power supply to the load device 12 are performed. The power control unit 14 converts the AC power supplied via the AC distribution board 11 into DC by an AC / DC converter (not shown) and charges the storage battery 13. Further, the power control unit 14 converts DC power discharged from the storage battery 13 into AC using a DC / AC converter (not shown), and supplies the AC power to the load device 12 via the AC distribution board 11.

  The power measuring unit 15 detects the input current input from the commercial power source 1 to the AC distribution board 11 by the current sensor 15a, and measures the input power from the commercial power source 1 based on the measurement result of the input current. Further, the power measuring unit 15 periodically outputs the measurement result of the input power to the command unit 16.

  The command unit 16 stores the threshold value input from the threshold value setting unit 17 in the storage unit 16a. Based on the result of comparing the current input power acquired from the power measurement unit 15 and the threshold value stored in the storage unit 16a in advance, the command unit 16 controls the control command (charge / discharge control of the storage battery 13 and the load device). Command to perform power supply control to the power control unit 14. Here, when the measurement result of the input power exceeds the threshold value, the command unit 16 sends a control command (hereinafter, this control command is referred to as a discharge command) for discharging the storage battery 13 to supply power to the load device 12 to the power control unit 14. Output. On the other hand, if the measurement result of the input power is less than the threshold value, the command unit 16 outputs a control command for charging the storage battery 13 with the commercial power source 1 (hereinafter, this control command is referred to as a charge command) to the power control unit 14. Note that the command unit 16 is realized by an arithmetic function of a computer, for example, by executing a program previously incorporated in the computer.

  The threshold setting unit 17 outputs a preset threshold to the command unit 16. Here, an average value of input power may be obtained in advance, and this average value may be set in the threshold setting unit 17 as a default value of the threshold. In addition, an existing input device such as a DIP switch, a keyboard, or a touch panel may be used as the threshold setting unit 17, and the threshold value may be input using such an input device. Then, a threshold value may be input.

  Here, the command unit 16 described above constitutes a power acquisition unit that acquires the measurement result of the input power from the power measurement unit 15. The command unit 16 also has a function as a power acquisition unit, and the threshold setting unit 17. The power control unit 14 (control unit) constitutes a power supply control device.

  Next, the operation of this system will be described based on the flowchart of FIG. The command unit 16 periodically starts the control operation. When the control operation is started, first, the command unit 16 determines whether or not there is an input from the power measurement unit 15 (S1). When the measurement result of the input power is input from the power measurement unit 15 (Yes in S1), the command unit 16 compares the measured value of the input power with the threshold value stored in the storage unit 16a (S2, S5). ).

  Here, if the measured value of the input power exceeds the threshold value (Yes in S2), the command unit 16 transmits a discharge command to the power control unit 14. For example, when the threshold value is 3 kW and the input power measurement result is 4 kW and exceeds the threshold value, the command unit 16 outputs a discharge command for discharging the excess 1 kW from the storage battery 13 to the power control unit 14. When the power control unit 14 receives the discharge command from the command unit 16, the power control unit 14 refers to the storage battery information from the storage battery 13 and determines whether discharge is possible. If the storage battery 13 is not over-discharged (No in S3), the power control unit 14 converts the DC power discharged from the storage battery 13 into alternating current to assist the AC distribution board 11 so as to assist the excess of 1 kW. Output (S4). If the storage battery 13 is overdischarged (Yes in S3), the power control unit 14 does not discharge the storage battery 13 and ends the process.

  On the other hand, if the measurement result of the input power is the same as the threshold value (Yes in S5), the command unit 16 ends the process without outputting a control command to the power control unit 14.

  If the measurement result of the input power is less than the threshold value (No in S5), the command unit 16 transmits a charge command to the power control unit 14. For example, when the threshold is 3 kW and the input power measurement result is 2 kW and less than the threshold, the command unit 16 outputs a charging command for charging the storage battery 13 with the insufficient 1 kW to the power control unit 14. When the power control unit 14 receives a charging command from the command unit 16, the power control unit 14 refers to the storage battery information from the storage battery 13 and determines whether charging is possible. If the storage battery 13 is not fully charged (No in S6), the power control unit 14 converts the AC power from the AC distribution board 11 into direct current by the AC / DC converter so that the storage battery 13 is charged with the insufficient 1 kW. Conversion is performed to charge the storage battery 13 (S7). If the storage battery 13 is fully charged (Yes in S6), the power control unit 14 ends the process without charging the storage battery 13.

  As described above, in the present embodiment, when the measurement result of the input power exceeds the predetermined threshold value, the command unit 16 outputs a control command for discharging the storage battery 13 and supplying power to the load device 12 in the consumer. Moreover, the instruction | command part 16 is outputting the control command which charges the storage battery 13 with the commercial power source 1, if the measurement result of input electric power is less than a threshold value.

  Thereby, since the input electric power from the commercial power source 1 becomes equal to the threshold value, the electric power demand of the consumer 10 can be leveled.

  Note that the storage capacity of the storage battery 13 is such that the excess power can be charged when the input power exceeds the threshold, and the shortage can be discharged when the input power becomes less than the threshold. An appropriate capacity value is set based on the threshold value.

  In addition, the cycle in which the power measurement unit 15 measures the input power, the cycle in which the storage battery 13 outputs the storage battery information to the power control unit 14, and the cycle in which the command unit 16 executes the control operation may be any period. It may be changed.

  By the way, in this embodiment, the threshold value setting unit 17 sets the threshold value as a constant value. However, the threshold value setting unit 17 may set the threshold value for each period. Table 1 is an example of the threshold value set for each period, and the threshold value is set higher in the season (6/1 to 9/30, 12/1 to 3/31) in which the power demand increases such as summer and winter, In other seasons (4/1 to 6/30, 10/1 to 11/30), the threshold value is set low.

このように、閾値設定部１７は期間毎に閾値を設定しているので、期間に応じて電力需要が変化する場合には、期間毎に閾値を変更することで、電力需要の変化に応じて最適な閾値を設定することができる。

Thus, since the threshold value setting unit 17 sets the threshold value for each period, when the power demand changes according to the period, the threshold value is changed for each period so that the power demand changes according to the change in the power demand. An optimal threshold can be set.

  It is also preferable that the threshold setting unit 17 sets a threshold in each time zone of the day. Table 2 is an example of threshold values set for each time zone, and the time zone from midnight to early morning (for example, from 23:00 to 6:59) when power demand decreases is a threshold value compared to other time zones. Is set low.

このように、閾値設定部１７は１日のうちの各時間帯で閾値を設定しているので、時間帯毎に電力需要が変化する場合には、時間帯毎に閾値を変更することで、電力需要の変化に応じて最適な閾値を設定することができる。

Thus, since the threshold value setting unit 17 sets the threshold value in each time zone of the day, when the power demand changes for each time zone, by changing the threshold value for each time zone, An optimum threshold value can be set according to a change in power demand.

  Note that the threshold setting unit 17 may set a threshold for each time period in each time slot of the day, and respond to changes in power demand even when the power demand changes depending on the period or time slot. The optimum threshold can be set.

  Moreover, the threshold value setting unit 17 may provide hysteresis for the threshold value, and can suppress frequent switching of charge / discharge when the input power is near the threshold value. The threshold setting unit 17 may set two thresholds (upper limit value and lower limit value). The command unit 16 outputs a discharge command when the input power exceeds the upper limit value, and when the input power becomes less than the lower limit value. A charging command is output, and neither discharging nor charging is performed when the input power is between the upper limit value and the lower limit value. Hysteresis may be provided for each of the upper limit value and the lower limit value.

(Embodiment 2)
A second embodiment will be described with reference to FIG. In the present embodiment, the power supply control device described in the first embodiment and the power supply system using the same are additionally provided with a solar cell 22 and a generated power measurement unit 23. In addition, since structures other than the solar cell 22 and the generated power measurement unit 23 are the same as those in the first embodiment, common constituent elements are denoted by the same reference numerals and description thereof is omitted.

  The generated power measuring unit 23 measures the generated power by the solar cell 22 and periodically transmits the measurement result to the threshold setting unit 17 as generated power information. In addition, the threshold setting unit 17 receives the result of measuring the power consumption by the load device 12 with the power sensor 18.

  Based on the measurement result of the generated power input from the generated power measurement unit 23 and the measurement result of the power consumption input from the power sensor 18, the threshold setting unit 17, for example, the total daily power consumption and the total generated power As a threshold, a value obtained by leveling the difference between the two values within one day is set. Note that, depending on the time of day, the generated power may exceed the power demand, and surplus power may be generated. However, this surplus power is charged in the storage battery 13, the input power from the commercial power source 1 exceeds the generated power, and When the input power from the power source 1 falls below the threshold value, the storage battery 13 is discharged. In this power supply system, the storage battery 13 is charged by the power from the commercial power source 1 and also by the generated power of the solar battery 22.

  As described above, since the threshold value setting unit 17 sets a value obtained by leveling the difference obtained by subtracting the total generated power from the total daily power consumption within one day as the threshold value, the power generation of the solar cell 22 that is a distributed power source The threshold can be set to an optimum value in consideration of the amount. For example, when the total power consumption per day is 7 kWh and the total generated power of the solar battery 22 is 3 kWh, a value obtained by leveling the difference 4 kWh in one day is set as a threshold, and the input power from the commercial power source 1 is Controlled to a threshold value.

  And since the input electric power from the commercial power source 1 becomes equal to the said threshold value, the input electric power from the commercial power source 1 can be equalized. In addition, when the threshold value setting part 17 sets a threshold value, it is preferable to set a threshold value with allowance, also considering the case where the generated power of the solar cell 22 decreases due to bad weather.

  Note that the solar cell 22 is an example of a distributed power source, and a fuel cell, a cogeneration device, or the like may be used as a distributed power source in addition to a power generating device that uses renewable energy such as a wind power generator or a small hydroelectric generator.

(Embodiment 3)
A power supply control device according to the third embodiment and a power supply system using the power supply control device will be described below. Since the configuration of the power supply system is the same as that of the first or second embodiment, common components are denoted by the same reference numerals and description thereof is omitted.

  The command unit 16 stores the measurement result of the input power input from the power measurement unit 15 in the storage unit 16a.

  The threshold setting unit 17 obtains an average value of the input power in the predetermined period based on the measurement result of the input power in the predetermined period stored in the storage unit 16a, and sets the average value as a threshold in the command unit 16. Table 3 is an example of the input power stored in the storage unit 16a, and the average value (average input power) of the input power for each day is stored for seven days, for example. The threshold setting unit 17 obtains the average input power in the above period (seven days immediately before) based on the measurement results (average input power) for seven days stored in the storage unit 16a. In this case, 4 kW And this value (4 kW) is set as the threshold value for the day (8/2).

このように本実施形態では、所定期間における入力電力（すなわち消費電力）の測定結果が記憶部１６ａに記憶されている。そして、閾値設定部１７は、記憶部１６ａに記憶された測定結果をもとに所定期間における入力電力の平均値（すなわち消費電力の平均値）を求め、この平均値を閾値として設定している。

As described above, in the present embodiment, the measurement result of the input power (that is, power consumption) in the predetermined period is stored in the storage unit 16a. Then, the threshold setting unit 17 obtains an average value of input power (that is, an average value of power consumption) for a predetermined period based on the measurement result stored in the storage unit 16a, and sets this average value as a threshold value. .

  Thereby, since the average value of the input electric power in the predetermined period is set as the threshold value, the threshold value can be set according to the usage state of the load device 12 at the customer 10, and therefore the storage battery 13 can be charged and discharged efficiently. it can.

  Note that the threshold setting unit 17 may determine the threshold as described above at an arbitrary timing within a predetermined period. For example, when the threshold value is determined from the average value for 7 days as described above, the timing for updating the threshold value may be determined at an arbitrary timing from every other day to every seventh day.

  Further, when the threshold is set for each period as described in the first embodiment, the threshold setting unit 17 obtains an average value of input power for each period in the past predetermined period (for example, a plurality of years) in advance. The average value may be set as a threshold value for each period of the following year.

  As described in the first embodiment, when a threshold is set for each time slot, the threshold setting unit 17 obtains an average value of input power for each time slot in advance in a predetermined period (for example, a plurality of days). What is necessary is just to set the average value as a threshold value in each time slot | zone on the next day.

(Embodiment 4)
A power supply control device according to the fourth embodiment and a power supply system using the power supply control device will be described below. Since the configuration of the power supply system is the same as that of the first or second embodiment, common components are denoted by the same reference numerals and description thereof is omitted.

  The command unit 16 stores the measurement result of the input power input from the power measurement unit 15 in the storage unit 16a.

  The threshold setting unit 17 obtains an input power average value on the day when the peak value of the input power is maximum within the predetermined period based on the measurement result of the input power in the predetermined period stored in the storage unit 16a. The power average value is set in the command unit 16 as a threshold value. Table 4 is an example of the input power stored in the storage unit 16a, and the average value and the peak value of the input power for each day are stored, for example, for seven days. In this example, the peak value is maximum on July 30 within a predetermined period, and the threshold setting unit 17 obtains the input power average value (4.5 kW) on this day, and uses this input power average value as a threshold. The command unit 16 is set.

このように本実施形態では、所定期間における入力電力の測定結果が記憶部１６ａに記憶されている。閾値設定部１７は、記憶部１６ａに記憶された測定結果をもとに、所定期間内で入力電力のピーク値が最大となる日の入力電力平均値を求め、この入力電力平均値を閾値として設定している。

Thus, in this embodiment, the measurement result of the input power in the predetermined period is stored in the storage unit 16a. Based on the measurement result stored in the storage unit 16a, the threshold setting unit 17 obtains an input power average value on the day when the peak value of the input power is maximum within a predetermined period, and uses the input power average value as a threshold value. It is set.

  Thereby, since the input power average value on the day when the peak value becomes the maximum in the predetermined period is set as the threshold value, the threshold value can be set in accordance with the usage state of the load device 12 at the consumer 10, so Discharging can be performed efficiently.

  Note that the threshold setting unit 17 may determine the threshold as described above at an arbitrary timing within the period. For example, if the predetermined period is 7 days as described above, the timing for updating the threshold may be determined at an arbitrary timing from every other day to every seventh day.

(Embodiment 5)
A power supply control device according to a fifth embodiment and a power supply system using the same will be described with reference to FIG. In the present embodiment, in the power supply system of the first embodiment, a contract capacity determination unit 19 and a presentation unit 20 are additionally provided. Since the configuration other than the contracted capacity determination unit 19 and the presentation unit 20 is the same as that of the first embodiment, common components are denoted by the same reference numerals, and description thereof is omitted.

  The contract capacity determination unit 19 receives a threshold value from the command unit 16, determines a value obtained by adding a predetermined amount (for example, about 5 A) to the current value corresponding to the threshold value as the contract capacity at the time of the electric power contract, and presents the display unit 20. Output to.

  The presentation unit 20 is composed of a device having a display monitor such as a viewer mounted on a wall, a portable viewer, a mobile phone, a personal computer, a television, and the like, and displays the contract capacity input from the contract capacity determination unit 19, Present to consumers.

  In this way, the contract capacity determination unit 19 determines the contract capacity of the electricity bill based on the threshold set by the threshold setting unit 17, so the contract capacity is reduced in accordance with the input power at the customer's house. Thus, electricity charges can be reduced. Moreover, since the value obtained by adding a predetermined amount to the current value corresponding to the threshold value is determined as the contract capacity, the possibility that the power exceeding the contract capacity is erroneously used can be reduced while the contract capacity is lowered. The current value added to the current value corresponding to the threshold value can be input using, for example, input means (not shown) provided in the command unit 16. As this input means, an existing input device such as a DIP switch, a keyboard, or a touch panel can be used, or a voice input from a microphone by an operator may be recognized to input a current value.

  Note that the contract capacity determination unit 19 and the presentation unit 20 described in the present embodiment may be additionally provided in the power supply system described in the other embodiments, and the same effects as described above are obtained.

(Embodiment 6)
A power supply control device of Embodiment 6 and a power supply system using the same will be described with reference to FIG. In this embodiment, in the power supply system of Embodiment 1, the presentation unit 20 and the storage battery information collection unit 21 are additionally provided. In addition, since structures other than the presentation part 20 and the storage battery information collection part 21 are the same as that of Embodiment 1, the same code | symbol is attached | subjected to a common component and the description is abbreviate | omitted.

  The storage battery information collection unit 21 collects instantaneous charge power when the storage battery 13 is charged, collects instantaneous discharge power when the storage battery 13 is discharged, and periodically transmits the collected information to the command unit 16.

  The command unit 16 stores the charge / discharge information (instantaneous charge power, instantaneous discharge power) of the storage battery 13 input from the storage battery information collection unit 21 in the storage unit 16a, and integrates the charge power and the discharge power to integrate the charge. Electric power and integrated discharge power are calculated. Then, the command unit 16 outputs the calculation result of the accumulated charge power and the accumulated discharge power to the presentation unit 20.

  Table 5 below shows an example of the result of calculating the charge integration power and the discharge integration power. The command unit 16 takes charge / discharge information from the storage battery information collection unit 21 every minute, and integrates the accumulated charge power or the accumulated discharge power from the instantaneous charge power or the instantaneous discharge power taken every minute. Note that the period during which the command unit 16 integrates the charge integrated power and the discharge integrated power is arbitrary, and the integration period can be changed to an arbitrary period using the input means provided in the command unit 16.

提示部２０は、例えば壁に備え付けられたビューワ、可搬型のビューワ、携帯電話、パソコン、テレビなどの表示モニタを有する機器からなり、指令部１６から入力された充電積算電力及び放電積算電力を表示する。したがって、需要家は、提示部２０に表示された充電積算電力及び放電積算電力から、蓄電池３による充放電の状況を把握することができる。

The presentation unit 20 includes a device having a display monitor such as a viewer, a portable viewer, a mobile phone, a personal computer, a television, and the like provided on the wall, and displays the accumulated charge power and the accumulated discharge power input from the command unit 16. To do. Therefore, the consumer can grasp the state of charging / discharging by the storage battery 3 from the charging integrated power and the discharging integrated power displayed on the presentation unit 20.

  Needless to say, the contract capacity determination unit 19 and the presentation unit 20 described in the present embodiment may be additionally provided in the power supply systems described in the embodiments other than the first embodiment.

(Embodiment 7)
A power supply control device according to a seventh embodiment and a power supply system using the same will be described with reference to FIG. In the present embodiment, in the power supply system of the first embodiment, when threshold information is input to the command unit 16 from the server 30 provided outside the consumer, the threshold is changed based on the threshold information. It has become. Since the basic configuration of the power supply system is the same as that of the first embodiment, common components are denoted by the same reference numerals and description thereof is omitted.

  The server 30 is connected to the command unit 16 provided in the customer 10 via a wide area communication network such as the Internet. The server 30 determines a threshold value to be set for each customer 10 based on, for example, season information, time information, user behavior information, and the like, and sends threshold information indicating the threshold setting contents to the command unit 16 at an arbitrary timing. Send.

  When receiving the threshold information transmitted from the server 30 outside the home, the command unit 16 changes the current threshold set by the threshold setting unit 17 based on the threshold information from the server 30.

  As described above, in the present embodiment, when threshold information transmitted from the outside of the customer is input to the command unit 16, the threshold is changed based on this threshold information.

  Thereby, since the threshold value set to the command part 16 of each consumer 10 can be changed from the outside, it can be automatically changed to the threshold value suitable for a use condition, without making a consumer conscious.

  In the power supply systems described in the embodiments other than the first embodiment, the command unit 16 may change the threshold according to the threshold information input from the outside, and the usage state can be changed without making the consumer aware of it. It can be automatically changed to a suitable threshold.

DESCRIPTION OF SYMBOLS 1 Commercial power supply 10 Consumer 11 AC distribution board 12 Load apparatus 13 Storage battery 14 Power control part (control part)
DESCRIPTION OF SYMBOLS 15 Electric power measurement part 15a Current sensor 16 Command part 16a Memory | storage part 17 Threshold value setting part

Claims (7)

A power acquisition unit for acquiring a measurement result of input power supplied from a commercial power source to a consumer side;
A threshold value setting unit for setting a threshold value of the input power;
When the measurement result of the input power exceeds the threshold value, a control command for discharging the storage battery charged with power supplied from a commercial power source and supplying power to the load device in the consumer is output, and the measurement of the input power is performed. If the result is less than the threshold value, a command unit that outputs a control command to charge the storage battery with a commercial power source;
A power supply control apparatus comprising: a control unit that controls charging / discharging of the storage battery and power supply to the load device in accordance with a control command from the command unit.   The threshold value setting unit sets the threshold value for each period, and the command unit outputs the control signal based on a result of comparing the threshold value of each period and the measurement result of the input power. The power supply control device according to 1.   The threshold value setting unit sets the threshold value in each time zone of a day, and the command unit outputs the control signal based on a result of comparing the measurement result of the input power with the threshold value in each time zone. The power supply control device according to claim 1, wherein the power supply control device is a power supply control device.   A storage unit for storing the measurement result of the input power in a predetermined period, and the threshold setting unit obtains an average value of the input power in the predetermined period based on the measurement result stored in the storage unit; The power supply control device according to claim 1, wherein a value is set as the threshold value.   A storage unit that stores the measurement result of the input power in a predetermined period, and the threshold setting unit has a maximum input power peak value in the predetermined period based on the measurement result stored in the storage unit; The power supply control device according to any one of claims 1 to 3, wherein an input power average value of a certain day is obtained and the input power average value is set as the threshold value.   A contract capacity determining unit that determines a contract capacity of an electricity bill based on the threshold set by the threshold setting unit; and a presentation unit that presents the contract capacity determined by the contract capacity determining unit to a consumer. The power supply control device according to any one of claims 1 to 5, further comprising: A power measuring unit that measures input power supplied from a commercial power source to the consumer side;
A storage battery installed on the consumer side and charged with power supplied from a commercial power source;
A power supply system comprising: the power supply control device according to any one of claims 1 to 6 provided on a consumer side.

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