JP2011250673A - Energy controller and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently supply electricity.SOLUTION: In an energy controller 19, a control part 24 obtains an output power value according to power outputted from a solar cell 13 and a fuel cell 14 and a power consumption value according to power consumed by a low voltage DC load 17 and a high voltage DC load 18. Based on the output power value and the power consumption value, a path for supplying power can be switched by controlling open and close of switches 25-1 to 25-5. The present invention is applicable, for example, to an energy controller of an electric power system having a plurality of power sources.

Description

  The present invention relates to an energy controller and a control method, and more particularly, to an energy controller and a control method that enable efficient power supply in a system having a plurality of power supplies and a plurality of loads.

  Conventionally, in a power system equipped with a photovoltaic power generation panel, the power generated by the photovoltaic power generation panel is converted into AC power by a power conditioner and then supplied to each load in the power system, or commercial power Returned to the grid.

  For example, Patent Literature 1 discloses a home automation system including a system controller that controls devices in the system according to the state of a solar power generator.

JP 2002-330352 A

  By the way, in recent years, not only solar power generation but also a power system that uses power generated by a small wind power generation or a fuel cell or power stored in a storage battery has been developed. In such a power system, since multiple power supplies and multiple loads are connected, the output power output from each power supply and the power consumption consumed by each load become unstable, and the entire system As a result, it may be difficult to perform efficient power supply.

  The present invention has been made in view of such a situation, and enables efficient power supply in a system having a plurality of power supplies and a plurality of loads.

  The energy controller of the present invention includes an acquisition unit that acquires an output power value corresponding to power output from a plurality of power sources, and a change unit that changes paths of power supplied from the plurality of power sources to a plurality of loads. And control means for controlling the changing means based on the output power value obtained by the obtaining means.

  The method for controlling an energy controller according to the present invention obtains an output power value corresponding to power output from a plurality of power supplies, and changes a path of power supplied from the plurality of power supplies to a plurality of loads. The method includes a step of controlling based on the power value.

  In such a configuration, the paths of power supplied from the plurality of power sources to the plurality of loads are changed based on the output power values corresponding to the power output from the plurality of power sources, so that efficient power supply is possible. It can be carried out.

  According to the energy controller and the control method of the present invention, efficient power supply can be performed.

It is a block diagram which shows the structural example of embodiment of the electric power system to which this invention is applied. It is a figure explaining the energy flow which adapts to the use condition of the electric power on a holiday and a weekday. It is a figure which shows the mode with respect to an electric vehicle and a storage battery. It is a figure explaining the relationship between a weather and electric power. It is a figure which shows an example of control of energy flow. It is a block diagram which shows the modification of an electric power system.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration example of an embodiment of a power system to which the present invention is applied. In the present specification, the term “system” represents the entire apparatus constituted by a plurality of apparatuses.

  The power system 11 is connected to a system 12 that supplies power from a commercial power source, and is provided with a solar cell 13, a fuel cell 14, and a storage battery 15. In the power system 11, power is supplied to each load of the AC load 16, the low voltage DC load 17, and the high voltage DC load 18.

  The power system 11 also includes an energy controller 19 that controls an energy flow (for example, a power flow) between each power source and each load, and a DC bus 20 that is used to supply DC power. . The energy controller 19 includes a PV DCAC converter 21, a bidirectional DCAC converter 22, a current detector 23, and a controller 24.

  In the power system 11, the power line from the grid 12 is connected to the PV DCAC converter 21 of the energy controller 19, and the power line that supplies power to the AC load 16 is connected to the bidirectional DCAC converter 22 of the energy controller 19. It is connected. That is, electric power is supplied from the system 12 to the AC load 16 via the energy controller 19. In the energy controller 19, the power line between the system 12 and the PV DCAC converter 21 and the power line between the AC load 16 and the bidirectional DCAC converter 22 are connected via the current detector 23. Has been.

  The power line from the solar cell 13 is connected to the PV DCAC converter 21 of the energy controller 19 via the switch 25-1, and is connected to the power line between the switch 25-1 and the PV DCAC converter 21. A DC bus 20 is connected. The power line from the fuel cell 14 is connected to the DC bus 20 via the switch 25-2, and the power line from the storage battery 15 is connected to the DC bus 20 via the bidirectional DCDC conversion unit 26 and the switch 25-3. Has been. The power line to the low voltage DC load 17 is connected to the DC bus 20 via the low voltage DCDC converter 27 and the switch 25-4, and the power line to the high voltage DC load 18 is connected to the high voltage DCDC converter. 28 and the switch 25-5 to be connected to the DC bus 20. In addition, a bidirectional DCAC conversion unit 22 of the energy controller 19 is connected to the DC bus 20.

  Further, a diode 29 is arranged between a connection point between the power line between the switch 25-1 and the PV DCAC conversion unit 21 and the DC bus 20, and a connection point between the switch 25-2 and the DC bus 20. . The diode 29 is supplied with power from the solar battery 13 to the storage battery 15, the low voltage DC load 17, and the high voltage DC load 18, while the power from the bidirectional DCAC converter 22, the storage battery 15, and the fuel cell 14 is supplied. It is a regulation means for regulating the flow into the DCAC converter 21 for PV.

  The electric power generated by the solar cell 13 is supplied to the PV DCAC converter 21, and also via the DC bus 20, the storage battery 15, the low voltage DC load 17, the high voltage DC load 18, and the bidirectional DCAC converter 22. To be supplied. Further, the solar cell 13 includes a monitoring and adjusting device 13A. The monitoring and adjusting device 13A measures the electric power generated by the solar cell 13 by a sensor (not shown), and the magnitude of the electric power output from the solar cell 13. Is supplied to the control unit 24 of the energy controller 19, and the output of the solar cell 13 is adjusted according to the control signal from the control unit 24.

  The electric power generated by the fuel cell 14 is supplied to the storage battery 15, the low voltage DC load 17, the high voltage DC load 18, and the bidirectional DCAC conversion unit 22 via the DC bus 20. Further, the fuel cell 14 includes a monitoring and adjusting device 14A. The monitoring and adjusting device 14A measures the power generated by the fuel cell 14 by a sensor (not shown), and the magnitude of the power output from the fuel cell 14 is measured. Is supplied to the control unit 24 of the energy controller 19, and the output of the fuel cell 14 is adjusted according to the control signal from the control unit 24.

  The storage battery 15 is, for example, a lithium ion storage battery, a lead storage battery, or the like, and the direct current power supplied from the direct current bus 20 is converted into a predetermined voltage by the bidirectional DCDC conversion unit 26 and supplied to accumulate the power. Means. In addition, as the storage battery 15, as will be described later with reference to FIG. 2, a storage battery mounted on an electric vehicle is also used.

  Here, in the power system 11, the direct current power generated in the solar cell 13 and the fuel cell 14 is supplied to the direct current bus 20, and the alternating current is converted into direct current in the bidirectional DCAC conversion unit 22 supplied from the system 12. Power is supplied. The DC bus 20 is capable of supplying power with a voltage of about 120 to 400 V, for example. In the design stage of the power system 11, a specified value of the voltage of power supplied using the DC bus 20 is determined. ing. Specifically, when the specified value is 300 V, which is the voltage of power output from the solar cell 13, the voltage of power output from the fuel cell 14 (for example, 50V) is set to 300 V by a booster (not shown). And then supplied to the DC bus 20.

  The bidirectional DCDC converter 26 converts the specified voltage power into a predetermined voltage suitable for charging the storage battery 15 (for example, 12V, 24V, etc.) and supplies the converted voltage to the storage battery 15. The stored electric power is converted into the above-mentioned specified voltage and supplied to the DC bus 20. In addition, the bidirectional DCDC converter 26 detects a stored power value indicating the amount of power stored in the storage battery 15, communicates with the control unit 24 of the energy controller 19, and is stored in the storage battery 15. The stored power value of power is notified to the control unit 24.

  The AC load 16 is a device that consumes AC power, such as a heat source device such as a microwave oven or a water heater. The AC load 16 is supplied with AC power from the system 12 via the current detection unit 23, and is also supplied with power converted into AC by the bidirectional DCAC conversion unit 22. Although not shown, when each device connected to the power system 11 as the AC load 16 includes a communication unit that communicates with the control unit 24 of the energy controller 19, the power consumed by each device The control unit 24 is notified of the power consumption value representing the magnitude.

  The low-voltage DC load 17 is a device that consumes low-voltage DC power, such as LED lighting, ventilation fans, telephones, and personal computers. The low-voltage DC load 17 is supplied with power of a specified voltage supplied via the DC bus 20 after being converted into, for example, a voltage of 48V by the low-voltage DCDC converter 27. Further, the low voltage DCDC converter 27 detects a power consumption value indicating the amount of power consumed by the low voltage DC load 17, communicates with the control unit 24 of the energy controller 19, and performs the low voltage DC load 17. The control unit 24 is notified of the power consumption value at.

  The high-voltage DC load 18 is a device that consumes high-voltage DC power, such as a refrigerator or an air conditioner. The high-voltage DC load 18 is supplied with power of a specified voltage supplied via the DC bus 20 after being converted into a voltage of 300 V, for example, by the high-voltage DCDC converter 28. Further, the high voltage DCDC converter 28 detects a power consumption value indicating the amount of power consumed by the high voltage DC load 18, communicates with the control unit 24 of the energy controller 19, and performs the high voltage DC load 18. The control unit 24 is notified of the power consumption value at.

  The PV DCAC converter 21 converts the DC power generated by the solar cell 13 into AC power and outputs it under the control of the controller 24.

  The bidirectional DCAC converter 22 converts the input DC power into AC power and outputs it under the control of the control unit 24, and converts the input AC power into DC power. Output. For example, the bidirectional DCAC converter 22 converts AC power supplied from the system 12 via the current detector 23, and stores the storage battery 15, the low-voltage DC load 17, and the high-voltage DC via the DC bus 20. DC power is supplied to the load 18. On the other hand, the bi-directional DCAC converter 22 converts DC power input via the DC bus 20 to supply AC power to the AC load 16 or AC to the system 12 via the current detector 23. Or return the power.

  The current detection unit 23 detects a current flowing through the arranged wiring and supplies a signal indicating a current value indicating the magnitude of the current to the control unit 24. The control unit 24 controls the outputs of the PV DCAC conversion unit 21 and the bidirectional DCAC conversion unit 22 according to the current value detected by the current detection unit 23.

  For example, the control unit 24 prevents the power output from the bidirectional DCAC conversion unit 22 from flowing into the system 12 based on the current value detected by the current detection unit 23, that is, the current detection unit 23 in FIG. The output of the bidirectional DCAC conversion unit 22 is adjusted so that no current passing from the right side to the left side is generated. Further, for example, when the power from the fuel cell 14 and the storage battery 15 can cover the power consumption of the AC load 16, the low voltage DC load 17, and the high voltage DC load 18, the control unit 24 consumes the AC load 16. While controlling the output of the bidirectional DCAC converter 22 according to the power, the output of the PV DCAC converter 21 is controlled so that all of the power generated by the solar cell 13 returns to the grid 12. That is, at this time, the control unit 24 performs control so that no current flows through the current detection unit 23.

  The control unit 24 also controls the entire power system 11 in addition to the control inside the energy controller 19. That is, the control unit 24 controls each unit of the power system 11 based on information acquired by communicating with each unit of the power system 11, and has the highest value at the present time (for example, reduction of CO2 emissions, power generation cost). The energy flow of the power system 11 is controlled so that the operation is performed. The control unit 24 communicates with each unit of the power system 11 to acquire information (information such as an output power value, a power consumption value, and a stored power value), and opens / closes the switches 25-1 to 25-5. Control means for controlling and outputting control signals to the monitoring and adjusting device 13A, the monitoring and adjusting device 14A, and the bidirectional DCDC converter 26 are provided.

  For example, the control unit 24 communicates with the monitoring adjustment device 13A and the monitoring adjustment device 14A to acquire output power values of the solar cell 13 and the fuel cell 14, respectively, and communicates with the bidirectional DCDC conversion unit 26 to communicate with the storage battery 15 Get the accumulated power value of. The control unit 24 communicates with the low voltage DCDC conversion unit 27 and the high voltage DCDC conversion unit 28 to acquire power consumption values in the low voltage DC load 17 and the high voltage DC load 18, respectively.

  Moreover, the control part 24 communicates with an external server via communication networks 30, such as the internet, for example, and acquires weather information. The control unit 24 has a timer function and a calendar function, and acquires information indicating time and day of the week (holiday or weekday).

  Based on these pieces of information, the control unit 24 controls the opening and closing of the switches 25-1 to 25-5 so that the energy efficiency in the power system 11 is improved, and the power path in the power system 11 is controlled. Is controlled (passive / active). Here, the switches 25-1 to 25-5 are changing means for changing the power path. In addition to changing the power path by the switches 25-1 to 25-5, for example, an adjustment means for adjusting power (energy) is provided instead of the switches 25-1 to 25-5 to change the power. Control (for example, reducing power) can be performed. The control unit 24 can control the power path based at least on the output power value.

  Moreover, the control part 24 is provided with the function which controls the output of the solar cell 13 based on MPPT (Maximum Power Point Tracking) control, for example. For example, the control unit 24 detects a shaded photovoltaic power generation panel among a plurality of photovoltaic power generation panels included in the solar cell 13 and performs control so as to achieve optimal power generation under the current sunshine conditions. . Moreover, the control part 24 detects the electric power output from each solar power generation panel with which the solar cell 13 is provided, and based on the comparison result with the output value etc. which are preset, the output value of another solar power generation panel, etc. And detecting a failure of the broken photovoltaic power generation panel.

  Furthermore, the control unit 24 controls the electric power converted into alternating current by the PV DCAC conversion unit 21 based on the electric power generated by the solar cell 13 or the power consumption of each part of the power system 11, and the DC bus 20 The electric power supplied to each part of the electric power system 11 and the electric power returned to the grid 12 are adjusted.

  Further, the control unit 24 controls the fuel cell 14 via the monitoring and adjusting device 14A so that the operation efficiency of the fuel cell 14 is optimized.

  In addition, the control unit 24 monitors (learns) a loss in the storage battery 15 and performs bidirectional DCDC conversion so that the storage battery 15 is operated with an optimal storage amount (for example, 30 to 80% of the capacity of the storage battery 15). The unit 26 is controlled to charge the storage battery 15. Further, the control unit 24 is based on output power values of the solar cell 13 and the fuel cell 14, power consumption values of the AC load 16, the low-voltage DC load 17, and the high-voltage DC load 18, time, day of the week, weather, and the like. Then, a power storage schedule for the storage battery 15 is created.

  Furthermore, for example, the control unit 24 detects the voltage value of the AC power in the system 12, and when the voltage value rises to the vicinity of an appropriate value (for example, 101V + 6V), the charging to the storage battery 15 is given priority. Take control. That is, the control unit 24 stops the power conversion by the PV DCAC conversion unit 21 and the power generated by the solar cell 13 is supplied to the system 12 in order to avoid that the voltage value of the system 12 becomes an appropriate value or more. While stopping returning, it controls so that the electric power generated by the solar cell 13 may be charged by the storage battery 15 by performing the power conversion by the bidirectional DCDC converter 26.

  In general, the power usage status varies depending on whether it is a holiday or a weekday. In the power system 11, the power supply path is switched to match the power usage status.

  For example, with reference to FIG. 2, an energy flow that suits the power usage state depending on whether it is a holiday or a weekday when the power system 11 of FIG. 1 is applied to an office will be described. The left side of FIG. 2 shows the energy flow during a holiday, and the right side of FIG. 2 shows the energy flow during weekdays.

  For example, it is desirable to reserve natural energy preferentially on holidays. That is, on a holiday, the electric power generated by the solar cell 13 and the fuel cell 14 is charged to the electric vehicle 15A (storage battery mounted on the electric vehicle) and the storage battery 15B, and power purchase from the system 12 is stopped. Such an energy flow is suitable. In a holiday office, it is assumed that there are no people, and power supply to the AC load 16, the low-voltage DC load 17, and the high-voltage DC load 18 is not performed.

  On the other hand, on weekdays, it is desirable that natural energy is used for power consumption by reducing the priority of power purchase. That is, on weekdays, the power generated by the solar cell 13 and the fuel cell 14 and the power stored in the storage battery 15B are preferentially supplied to the AC load 16, the low-voltage DC load 17, and the high-voltage DC load 18. In addition, an energy flow from which power is purchased from the grid 12 when such power is insufficient is suitable. The electric power stored in the electric vehicle 15A is used by the electric vehicle 15A alone.

  Here, as a mode which the control part 24 selects about charge and discharge with respect to 15 A of electric vehicles, and charge and discharge with respect to the storage battery 15B, there exists a mode as shown in FIG.

  That is, for the electric vehicle 15A, there are a preferential charging mode, a mode in which power generation by the solar battery 13 is predicted and charging, and a mode in which the operation of the electric vehicle 15A is predicted and charging. In addition, for the storage battery 15B, a mode for preferentially charging, a mode for preferentially discharging, a mode for charging or discharging in sequence, a mode for charging using midnight power, and a standby (discharging) at midnight power ) Mode. The charging or discharging mode is a mode in which charging is performed if the voltage of the storage battery 15B is less than the voltage of the DC bus 20, and discharging is performed if the voltage of the storage battery 15B is equal to or higher than the voltage of the DC bus 20. is there.

  Next, with reference to FIG. 4, the relationship between weather and electric power will be described.

  As shown in FIG. 4, when the weather is fine, the solar cell 13 can obtain the power generation as specified, the electric power becomes surplus, and the electricity cost tends to be cheap. Therefore, there is a time shift (flexibility) in which power is actively consumed in each load and the storage battery 15 is positively charged. In addition, since the electricity bill is cheap but the power is surplus, there is a spatial shift in which power is to be transmitted to the grid 12.

  On the other hand, when the weather is cloudy, the solar cell 13 cannot obtain power generation as specified, the power is insufficient, and the electricity cost tends to be high. For this reason, there is a time shift in which consumption at each load is shifted (delayed) and power stored in the storage battery 15 is to be sold. Moreover, since the electricity bill is high, but the power is unpredictable, there is a spatial shift in that it is desired to purchase power from the grid 12.

  And in the electric power system 11, based on the relationship between such electric power and the weather and the use state of electric power as described with reference to FIG. 2, the control unit 24 of the energy controller 19 changes the energy flow. Control.

  FIG. 5 shows an example of energy flow control by the control unit 24.

  For example, on weekdays, when the day's weather is sunny and the next day's weather is also sunny, the electricity bill (electricity charge) is low, so the control unit 24 uses power at each load as much as possible. Perform such control. That is, the control unit 24 performs control such that the electric vehicle 15A is charged at night and the storage battery 15B is discharged so that the electric power of the storage battery 15B is charged to the electric vehicle 15A. In addition, the control unit 24 controls so that the electric power generated by the solar cell 13 is used in the load during the daytime, selects a mode for charging or discharging the storage battery 15B as soon as possible, and the electric vehicle For 15A, control is performed so that charging is not performed if there is no problem in operation.

  On weekdays, when the day's weather is sunny and the next day's weather is cloudy or rainy, the electricity bill is somewhat cheap, so the control unit 24 performs control to accumulate power as much as possible. Do. That is, at night, the control unit 24 selects a mode that prioritizes charging for the electric vehicle 15A, and for the storage battery 15B, according to the remaining amount accumulated in the storage battery 15B at that time. Control is performed to determine whether or not to perform charging. Moreover, the control part 24 controls so that the electric power generated by the solar cell 13 is charged in the storage battery 15B during the daytime, selects a mode in which charging is prioritized for the storage battery 15B, and sets the electric vehicle 15A. Also controls to charge.

  On weekdays, when the current day's weather is cloudy or rainy and the next day's weather is also cloudy or rainy, since the electricity bill is high, the control unit 24 uses the power of the storage battery 15B as much as possible. Control. That is, the control unit 24 performs control such that the electric vehicle 15A and the storage battery 15B are charged at night. Moreover, the control part 24 controls so that the electric power generated by the solar battery 13 is used in the load during the daytime, selects a mode in which discharging is given priority to the storage battery 15B, and the electric vehicle 15A. Performs control such that charging is not performed if there is no problem with the operation of the electric vehicle 15A.

  In addition, on Saturdays and Sundays (special days), which are holidays, since the electricity bill is the cheapest, the control unit 24 performs control to accumulate electric power. That is, the control unit 24 controls the electric vehicle 15A and the storage battery 15B so that the shortage in the solar battery 13 is charged at night so that the electric power of the storage battery 15B is charged in the electric vehicle 15A. Then, control is performed to discharge the storage battery 15B. In addition, the control unit 24 controls so that the electric power generated by the solar battery 13 is stored in the electric vehicle 15A and the storage battery 15B during the daytime, selects a mode in which charging is prioritized for the storage battery 15B, Control is performed to charge the automobile 15A.

  In this way, the control unit 24 performs control based on the priority order in which natural energy is used most preferentially, then night power is used, and daytime power is used last. Moreover, since the electricity bill (energy unit price) fluctuates according to the weather, the control unit 24 performs control so as to reduce the cost.

  Furthermore, the control unit 24 estimates an electric charge (electricity charge) for the electric power supplied from the grid 12 based on, for example, weather (amount of solar radiation), day of the week (holiday or weekday), and the estimated electric charge Is below a certain reference charge, control is performed such that the electric power generated by the solar cell 13 is charged into the electric vehicle 15A or the storage battery 15B. The reference fee is obtained in advance based on the cost required for power generation by the solar cell 13. Moreover, when the electric power system 11 is provided with the power source which produces | generates electric power using natural energy like wind power generation other than the solar cell 13, the control part 24 is the estimated electric charge below a fixed standard charge. In such a case, control is performed such that the output power from the power source using such natural energy is charged in the electric vehicle 15A or the storage battery 15B.

  In addition, the control unit 24 can control the energy flow not only based on the current day's weather and the next day's weather, but also based on the current power state and the predicted power state. . Here, the current power status includes the output power generation value of the solar cell 13 according to the current weather, the current stored power value of the electric vehicle 15A and the storage battery 15B, the AC load 16, the low voltage DC load 17, and the high This is a comprehensive situation obtained from the current power consumption value of the voltage DC load 18.

  Further, the predicted power status depends on the output power generation value of the solar cell 13 predicted according to the weather after the next day, and the electric vehicle 15A, the AC load 16, the low voltage DC load 17, and the high voltage DC load 18. This is a comprehensive situation obtained from the power consumption value expected to be consumed. In addition, the power consumption by the electric vehicle 15A can be predicted by, for example, accumulating the use history of the electric vehicle 15A (change in use timing, charge amount, etc.). Similarly, the power consumption by the AC load 16, the low voltage DC load 17, and the high voltage DC load 18 can be predicted by accumulating the history of each power consumption.

  And the control part 24 controls an energy flow so that the optimal electric power operation is performed as the whole electric power system 11 based on the present electric power condition and the estimated electric power condition.

  Specifically, the current power generation by the solar cell 13 is small (that is, the current weather is cloudy or rainy) and the power generation by the solar cell 13 the next day is predicted to be large (that is, the next day's weather is sunny). If it is predicted that the electric vehicle 15A is low but the electric vehicle 15A will not be used the next day, the control unit 24 uses the electric power generated by the solar cell 13 the next day. Control is performed to charge 15A. For example, when the electric vehicle 15A is regularly used at the same timing, the control unit 24 predicts the timing at which the electric vehicle 15A is used, and confirms the current stored power value of the electric vehicle 15A. Then, control is performed so that the electric vehicle 15A is fully charged by that timing.

  The control unit 24 can perform power on / off control for the AC load 16, the low-voltage DC load 17, and the high-voltage DC load 18. For example, the control part 24 can acquire the change of the power consumption value for every time, when the wattmeter is installed in each load. Then, the control unit 24 compares the change in the power consumption value with the registered data, and controls the power supply to be turned off for a load that does not fluctuate for a long time. Further, the control unit 24 accumulates changes in the power consumption value for a predetermined period, and for example, turns off the power supply of the load as compared with the accumulated data before a certain period (for example, one week ago). It can be determined whether or not.

  Further, the control unit 24 determines whether or not to turn off the load power based on the time, a behavior pattern based on a calendar, a family structure, a lifestyle, and the like in addition to the pattern of the power consumption value change. can do. Further, the control unit 24 can control switching to the energy saving mode in addition to the power on / off control.

  For example, if the control unit 24 determines that the user has gone out and no one is in the house based on the pattern of change in the power consumption value, forgetting to turn it off if the lighting is on. As turn off the lighting.

  Further, the control unit 24 can perform power on / off control for the AC load 16, the low-voltage DC load 17, and the high-voltage DC load 18 according to the priority of load control registered in advance. . For example, a refrigerator can be set to a low priority because the power is not turned off, and a television receiver can be set to a high priority. Moreover, you may set so that a priority may be changed with a day of the week or time.

  In addition, when the storage battery 15 is composed of a plurality of types of storage batteries, the control unit 24 controls the switching of the plurality of types of storage batteries, or uses the power demand and midnight power to reduce the minimum capacity of the storage battery 15. It is possible to control the charging method or to control the charging method when a lithium ion storage battery is used as the storage battery 15.

  In addition, the control unit 24 communicates (exchanges information) with a control unit included in another power system via the communication network 30 and responds to power demand in the region (a plurality of houses and a plurality of buildings). You can also control it. That is, centralized management by a plurality of power systems can be realized. For example, when acquiring a power transmission request from another power system, the control unit 24 returns the power corresponding to the request to the system 12. In addition, the control unit 24 may transmit a power transmission request to another power system. Furthermore, when power supply from the grid 12 is interrupted during a disaster or the like, power is transmitted and received between the power systems 11.

  In addition, the control unit 24 acquires electricity rate information from the power company via the communication network 30 and uses the power generated in the solar cell 13 and the fuel cell 14 according to the electricity rate, or from the system 12 It is possible to determine whether to use the power. The control unit 24 may acquire the electricity bill information via a personal computer (not shown). For example, the control unit 24 notifies the user of a time zone suitable for using a load with large power consumption (for example, a dishwasher) based on the electricity rate information, or the control unit 24 turns on the load directly. / Can be turned off. Specifically, when the electricity bill after 11:00 pm is reduced, the control unit 24 performs control to start the operation of the dishwasher after 11:00 pm.

  Next, a modification of the power system 11 will be described with reference to FIG. Note that FIG. 6 shows only a portion having a configuration different from that of the power system 11 of FIG.

  As illustrated in FIG. 6, the power system 11 ′ is configured such that the path between the solar cell 13 and the storage battery 15 is switched by a switch 25-6. 6 is configured in the same manner as the power system 11 in FIG. 1, and a detailed description thereof is omitted.

  In the electric power system 11 ′, a path in which the solar battery 13 and the storage battery 15 are directly connected and a path in which the solar battery 13 and the storage battery 15 are connected through the PV control unit 50 are set by the switch 25-6. Can be switched. The PV control unit 50 has a function of controlling the output of the solar cell 13 based on MPPT control.

  The switching of the route by the switch 25-6 is performed by the control unit 24 of the energy controller 19, and the control unit 24, for example, based on the power generated by the solar cell 13, for example, when the power is generated in fine weather, Switch routes between early morning and when there is little power generation due to cloudy weather.

  For example, when there is little power generation of the solar cell 13 and priority is given to avoiding the occurrence of conversion loss due to the PVPT unit 50 performing MPPT control, the solar cell 13 and the storage battery 15 are directly connected. The path is selected, and the storage battery 15 is charged by leaving the voltage of the storage battery 15 to the left. On the other hand, even if there is a lot of power generation of the solar cell 13 and conversion loss due to the PV control unit 50 performing MPPT control, when priority is given to taking out power suitable for the solar cell 13, A path through which the storage battery 15 is connected via the PV control unit 50 is selected.

  Further, when the storage battery 15 is directly connected to the DC bus 20 and the electric power stored in the storage battery 15 is used, the electric power can be used at a high efficiency of the inverter. Moreover, when using the electric power output from the PV control part 50, for example, even if the weather is bad and the electric power generated by the solar cell 13 is small, it can be used with low inverter efficiency.

  In this way, the PV control unit 50 determines whether or not to perform MPPT control, and by selecting a route so that the maximum output can be obtained, the power system 11 ′ can be operated more efficiently.

  As described above, in the power system 11, the control unit 24 of the energy controller 19 includes the output power values of the solar cell 13 and the fuel cell 14, the stored power value of the storage battery 15, the AC load 16, the low voltage DC load 17, Then, the power consumption value of the high voltage DC load 18 is acquired, and the switching of the switches 25-1 to 25-5 is controlled to supply the AC load 16, the low voltage DC load 17, and the high voltage DC load 18. Therefore, more efficient power supply can be performed. That is, in the power system 11, integrated control is performed by the control unit 24, so that the solar cell is efficiently operated as the entire power system 11 without generating power arbitrarily with a plurality of power sources. 13 and the fuel cell 14 generate power.

  Further, in the power system 11, since DCAC conversion is performed in the energy controller 19, compared with a system in which a photovoltaic power generation panel and a fuel cell each having a converter are combined, there is no duplication of equipment and waste. Can be omitted.

  Moreover, in the electric power system 11, generation | occurrence | production of CO2 can be suppressed more by the control part 24 controlling so that the electric power generation by the solar cell 13 may be given priority over the electric power generation by the fuel cell 14. When the power generated by the solar battery 13 is insufficient compared to the power consumption, the power stored in the storage battery 15 can be used. With such an operation, the power system 11 can be configured to have a higher value, for example, a system that can reduce CO2 emission or reduce power generation costs.

  Moreover, in the electric power system 11, since the electric power returned to the system | strain 12 is controllable, generation | occurrence | production is anticipated by suppressing that the voltage of the system | strain 12 rises from an appropriate value, or the spread of a solar cell, for example. Generation of surplus power can be suppressed.

  Here, since the voltage of the grid 12 is often kept constant at this appropriate value, the power is obtained by measuring the current flowing from the grid 12 into the power system 11. For example, the voltage in the home is 200 V or 100 V, and by setting the voltage value in the control unit 24, the control unit 24 is based on the current value of the current flowing from the system 12 into the power system 11. The power from the grid 12 can be calculated. In the present embodiment, the power value (output power value, power consumption value, accumulated power value) represents the power level at a certain time (instantaneous power), and is the power level at a predetermined time. The information handled by the energy controller 19 including the amount (integrated power) may be instantaneous power or integrated power.

  In the power system 11 of FIG. 1, the storage battery 15 is connected to the DC bus 20 via the bidirectional DCDC conversion unit 26, and forced discharge or charging (storage capacity of the storage battery 15 is performed by the bidirectional DCDC conversion unit 26. The charging is controlled based on the upper limit value corresponding to. On the other hand, for example, the storage battery 15 is directly connected to the DC bus 20, and the storage battery 15 is discharged or charged according to the relationship between the voltage of the storage battery 15 and the voltage of the DC bus 20. It may be.

  In the power system 11, a breaker that cuts off the power supply when a current exceeding a specified current value flows due to an overload or a short circuit is connected to a power line to which the DC bus 20 and each unit are connected. ing.

  Furthermore, in addition to the solar cell 13 and the fuel cell 14, the present invention can be applied to various energy devices such as a heat pump hot water supply, a heat storage / ice heat storage air conditioner, and a system including a wind power generator. it can.

  In addition, this invention is the structure by which the PV control part was provided for every several photovoltaic power generation panel which comprises the solar cell 13 other than the structure which controls the solar cell 13 in the control part 24 or the PV control part 50. It can also be applied to other power systems. As described above, when the PV control unit is provided for each of the plurality of photovoltaic power generation panels constituting the solar battery 13, it is possible to perform control such that the maximum output is obtained for each photovoltaic power generation panel. Overall, optimum output power can be obtained.

  The control unit 24 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a flash memory (for example, an EEPROM (Electronically Erasable and Programmable Read Only Memory)), and the like. Each part of the power system 11 is controlled by loading a program stored in the ROM or flash memory into the RAM and executing it. Note that the program executed by the CPU can be downloaded to the flash memory and updated as appropriate in addition to those stored in the ROM and the flash memory in advance.

  The embodiment of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 11 Electric power system 12 System | strain 13 Solar cell 14 Fuel cell 15 Storage battery 16 AC load 17 Low voltage DC load 18 High voltage DC load 19 Energy controller 20 DC bus 21 PV DCAC conversion part 22 Bidirectional DCAC conversion part 23 Current detection part 24 Control Part

Claims (9)

Acquisition means for acquiring an output power value corresponding to the power output from a plurality of power sources;
Changing means for changing paths of power supplied from the plurality of power supplies to the plurality of loads;
Control means for controlling the changing means based on the output power value acquired by the acquiring means. An energy controller comprising: The apparatus further comprises adjusting means for adjusting power supplied from the plurality of power supplies to the plurality of loads,
The energy controller according to claim 1, wherein the control unit controls the adjustment unit based on the output power value. The acquisition means further acquires a power consumption value corresponding to the power consumed by the plurality of loads,
The energy controller according to claim 1, wherein the control unit performs control based on the power consumption value. The power wiring that connects the plurality of power supplies and the plurality of loads is connected to storage means for storing power,
The acquisition means further acquires a stored power value corresponding to the power stored in the storage means,
The control means controls the accumulation of electric power in the accumulating means and the output of electric power accumulated in the accumulating means based on the output power value, the consumed power value, and the accumulated electric power value. The energy controller according to claim 3. It further comprises an estimation means for estimating an electricity rate for power supplied from the grid,
The control unit stores, in the storage unit, output power from a power source that generates power using natural energy among the plurality of power sources when the estimated electricity rate is equal to or less than a predetermined reference rate. The energy controller according to claim 4, wherein the path by the changing unit is changed as follows. As the power source, at least solar power generation means is used,
The control means controls the solar power generation means so as to obtain the maximum output based on an output power value corresponding to the power output from the solar power generation means acquired by the acquisition means. The energy controller according to any one of claims 1 to 5. The acquisition means further acquires information indicating time and information indicating weather,
The energy controller according to any one of claims 1 to 6, wherein the control unit controls the changing unit based on information indicating the time and information indicating the weather. The energy controller according to claim 1, wherein the control unit controls the changing unit based on a current power state and a predicted power state. Get the output power value according to the power output from multiple power sources,
A method for controlling an energy controller, comprising: controlling, based on the output power value, a change in a path of power supplied from the plurality of power sources to a plurality of loads.

Images