JP2014093906A - Power supply device and emergency power source provision system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device and an emergency power source provision system for suppressing unauthorized use and mischief to a power source at normal times so as to constantly supply power at emergency times due to blackout or disaster.SOLUTION: When a power supply device 10 does not detect power supply from a commercial power system 30 due to blackout, disaster, or an accident, the emergency power source provision system supplies power from an accumulator battery 15 in the own device 10, a solar battery 40, or an accumulator battery 51 in an electric vehicle 50 to a locker device 20. The locker device 20 provides the supplied power to the outside as a power source by a receptacle hole or a plug installed in the own device 20.

Description

  The present invention relates to a power supply device and an emergency power supply system, and more particularly to a power supply device and an emergency power supply system that provide power in a common space in the event of an emergency such as a power failure.

  In modern times, there are a lot of devices that require power, such as refrigerators, TV home appliances, communication devices such as mobile phones and PCs, and lighting. In order to spend a comfortable life, it is essential to stably supply power to these devices.

However, a power outage may occur due to the occurrence of a disaster such as an earthquake or fire, or other accidents, and power may not be stably supplied.
As a solution to such a problem, a power storage system disclosed in Patent Document 1 has been proposed.
The power storage system disclosed in Patent Document 1 includes a storage battery and a solar power generation system. When power supply from the commercial power system is interrupted due to a power failure or a disaster, power is supplied from the commercial power system to the storage battery or the solar power generation system. The power supply is switched, and power is stably supplied from a power output terminal comprising a power plug or a power outlet to a load such as a refrigerator, a television, or some lighting.

Utility Model Registration No. 3171974

  However, as described above, the power storage system disclosed in Patent Document 1 has a power output terminal composed of a power plug or a power outlet, so that it can be freely used in normal times in addition to an emergency such as a power failure. Therefore, especially in places where multiple specific / unspecified people are active, such as condominiums such as condominiums, shared spaces in stations, government offices, etc., malfunctions due to mischief, etc. have already been used in normal times. Therefore, there is a problem that power cannot be supplied to a really necessary load (equipment) when an emergency occurs.

  The present invention has been made in view of the above problems, and suppresses unauthorized use and mischief of the power supply during normal times, and stably supplies power in the event of an emergency such as a power outage or disaster. An object is to provide a supply device and an emergency power supply system.

  In order to achieve such an object, the present invention is a power supply device that supplies commercial power in a normal state, and has a commercial power monitoring unit that detects commercial power, and the commercial power monitoring unit detects supply of commercial power. When no power is supplied, the power supply from the commercial power is switched to the power supply from an emergency power source other than the commercial power.

  Moreover, this invention is an emergency power supply system which has the said electric power supply apparatus, and the rocker apparatus which has one or more accommodating parts normally locked by door closing, and is supplied with electric power by an electric power supply apparatus, In an emergency, the door of the storage unit is unlocked, and the power supplied from the power supply device can be provided to the outside from an outlet provided in the storage unit.

  Further, according to the emergency power supply system of the present invention, the power supply apparatus detects a commercial power abnormality signal indicating that an abnormality has occurred in the commercial power supply when the commercial power monitoring unit no longer detects the commercial power supply. When the locker device detects that the commercial power abnormality signal is input from the power supply device, the locker device unlocks the door of the housing portion and provides the power supplied from the power supply device to the outside. It is characterized by that.

  In addition, the emergency power supply system according to the present invention further includes, as an emergency power source, a solar cell that generates power from solar energy, and the power supply device is configured such that the commercial power monitoring unit no longer detects supply of commercial power. The power supplied from the solar cell is supplied to the locker device.

  In the emergency power supply system according to the present invention, the power supply device further includes a storage battery that stores power as an emergency power supply, and the storage battery is not detected when the commercial power monitoring unit detects the supply of power from the commercial power. The power is supplied to the locker device.

  The emergency power supply system according to the present invention further includes a battery of the electric vehicle and a power feeder that is connected to the battery of the electric vehicle and supplies electric power to the connected electric vehicle. When the supply of power from the power is not detected, the power feeder supplies power from the battery of the connected electric vehicle to the locker device.

The power supply device according to the present invention has a commercial power monitoring unit that detects commercial power, and when the commercial power monitoring unit no longer detects supply of commercial power, power from an emergency power source other than commercial power is detected. Switch to supply.
Further, an emergency power supply system according to the present invention includes the power supply device and a locker device that has one or more storage units that are normally closed and locked and that is supplied with power by the power supply device. In an emergency, the door of the housing is unlocked, and the power supplied from the power supply device is controlled to be provided from the outlet provided in the housing.
Therefore, according to the present invention, it is possible to suppress unauthorized use or mischief of the power supply during normal times and stably supply power in the event of an emergency such as a power outage or disaster.

It is a figure which shows the structure of the emergency power supply system in embodiment of this invention. It is an external view of the locker device in an embodiment of the present invention. In an emergency power supply system in an embodiment of the present invention, it is a figure showing a flow of current at the time of a normal operation mode. In an emergency power supply system in an embodiment of the present invention, it is a figure showing a flow of current at the time of normal night mode. It is a figure which shows the flow of the electric current in the case of normal charging operation in the emergency power supply system in embodiment of this invention. In an emergency power supply system in an embodiment of the present invention, it is a figure showing a current flow in the case of an emergency operation mode. It is a sequence chart which shows the flow of operation | movement in the self-sustained operation mode in emergency by the emergency power supply system in embodiment of this invention. It is a figure which shows the flow of the electric current in the case of the emergency charging operation in the emergency power supply system in embodiment of this invention.

<Overview>
The emergency power supply system according to the embodiment of the present invention is used when the power supply from the commercial power system is stopped due to a power failure or the like in an apartment house or the like that supplies power to the apartment house or the like from the commercial power system and solar cells in normal times. , Unlocking the door of the locker box of the locker device, making the power output terminal such as a socket hole provided in the locker box available, and supplying power from the solar battery and the storage battery to the power output terminal It is characterized by supply.
Hereinafter, in the present embodiment, “normal” indicates a state in which power can be supplied from a commercial power system in an apartment house, etc., and “emergency” refers to a commercial power system due to a power failure, disaster, accident, or the like. It is assumed that the power supply from is stopped.

<Configuration>
(1) Overall Configuration of Emergency Power Supply System FIG. 1 is a diagram showing a configuration of an emergency power supply system according to an embodiment of the present invention.
As shown in the figure, the emergency power supply system receives a power supply from the power supply device 10 that supplies power in an emergency such as a power failure, and supplies the power to an external electrical device. A locker device 20 that performs normal operation, a commercial power system 30 that supplies power to an external electrical device including the power supply device 10, and a solar cell that performs solar power generation and supplies the generated power to the power supply device 10 40 and a storage battery 51, and an electric vehicle 50 that travels using the storage battery 51 as a power source, supplies power to the electric vehicle 50 to charge the storage battery 51, and supplies power from the storage battery 51 in an emergency. A power supply 60 that receives and supplies power to the locker device 20, and a load 1 such as an electric device that receives power from the commercial power system 30 and the solar battery 40 in normal times. 0 and configured to have a.

The emergency power supply system configured as described above is configured such that when the power supply device 10 no longer detects power supply from the commercial power system 30 due to a power failure, a disaster, an accident, or the like, the storage battery 15 and the solar cell in the own device 10 40, the electric power from the storage battery 51 in the electric vehicle 50 is supplied to the locker device 20, and the locker device 20 supplies the supplied electric power to the outside through an outlet hole or a plug provided in the own device 20. Is.
By configuring in this way, the emergency power supply system can be used in an emergency in a housing complex or public place even when power supply from the commercial power system 30 cannot be expected due to a power failure, disaster or accident. It is possible to provide a minimum power source such as a communication device and lighting.

(2) Configuration of Power Supply Device 10 The power supply device 10 is a set of condominiums or the like when a disaster such as a power failure or an earthquake occurs and it is difficult to stably supply power from the commercial power system 30. It is a device that supplies power in a common space in a house.
As shown in the figure, a power supply control unit 11 configured by a CPU or the like and controlling the operation of the entire power supply apparatus 10;
A backflow prevention diode 12 for preventing a current from flowing back from the commercial power system 30 or the storage batteries 15, 51 to the solar battery 40 side;
A DC / DC converter 13 for converting (boosting) the voltage of power supplied from the solar cell 40;
An inverter 14 for converting DC power from the solar cell 40 boosted by the DC / DC converter 13 into AC power;
A storage battery 15 in which electric power supplied from the commercial power system 30 and the solar battery 40 is stored;
A charger 16 for charging and discharging the storage battery 15;
Circuit switching units 17 and 18 for switching power supply sources and supply destinations;
A commercial power monitoring unit 101 that monitors the state of power supply from the commercial power system 30 to the power supply device 10;
A solar cell monitoring unit 102 that monitors the state of power supply from the solar cell 40 to the power supply device 10;
And a storage battery monitoring unit 103 that monitors the storage state of the storage battery 15.

The power supply control unit 11 is a signal (commercial power system measurement signal) indicating the state of power supply by the commercial power system 30 from the commercial power monitoring unit 101 and a signal indicating the state of power supply by the solar cell 40 from the solar cell monitoring unit 102. (Solar cell measurement signal), a signal (storage battery measurement signal) indicating the storage state of the storage battery 15 from the storage battery monitoring unit 103, and a signal (vehicle storage measurement signal) indicating the storage state of the storage battery 51 of the electric vehicle 50 from the feeder 60, respectively. When input, the operation of the circuit switching units 17 and 18 and the DC / DC converter 13 is controlled based on these input signals.
The power supply control unit 11 stores a value of the power supply amount necessary for the load 100.
In normal times, the power supply control unit 11 compares the amount of power currently supplied by the solar cell 40 from the solar cell monitoring unit 102 with the amount of power supplied to the load 100, and When the supply power can be sufficiently supplied to the load 100, the surplus power of the solar cell 40 is supplied to the commercial power system 30 for power sale.
On the other hand, when the supply power from the solar cell 40 alone cannot be sufficiently supplied to the load 100, the shortage of power is supplied from the commercial power system 30 to the load 100.
Further, the power supply control unit 11 controls each part in the power supply device 10 so that power is supplied from the solar cell 40 and the storage battery 15 to the locker device 20 in an emergency when the power supply from the commercial power system 30 is stopped. Provide emergency power in common spaces such as condominiums.

  The backflow prevention diode 12 has an input terminal connected to the solar cell 40 and an output terminal connected to the DC / DC converter 13, and the current from the commercial power system 30 and the storage batteries 15 and 51 to the solar cell 40 side. Prevent backflow.

  The DC / DC converter 13 has an input terminal connected to the backflow prevention diode 12 and an output terminal connected to the circuit switching unit 17, and boosts the voltage of the power supplied from the solar cell 40 via the backflow prevention diode 12. Then, the boosted power supplied from the solar cell 40 is output to the circuit switching unit 17.

The input / output terminals of the inverter 14 are connected to the circuit switching units 17 and 18, respectively.
The inverter 14 is input from the solar battery 40 via the backflow prevention diode 12, the DC / DC converter 13 and the circuit switching unit 17, and input from the storage battery 15 via the charger 16 and the circuit switching unit 17. The DC power and the DC power input from the storage battery 51 via the power feeder 60 and the circuit switching unit 17 are each converted into AC power and output to the circuit switching unit 18.
Further, the inverter 14 converts AC power input from the commercial power system 30 via the circuit switching unit 18 into DC power and outputs the DC power to the charger 16 and the power feeder 60.

  The storage battery 15 is connected to the circuit switching unit 17 via the charger 16 and stores the power supplied from the commercial power system 30 or the solar battery 40. The stored electric power is supplied to the locker device 20 as an emergency power source in an emergency such as a power failure.

The charger 16 has input / output terminals connected to the storage battery 15 and the circuit switching unit 17, respectively. The battery 16 charges the storage battery 15 with power supplied from the commercial power system 30 or the solar battery 40, and in the event of an emergency, the storage battery 15 Is supplied to the locker device 20 as an emergency power source.
The charger 16 charges the storage battery 15 with the DC power supplied from the solar battery 40, and charges the storage battery 15 in the same manner after converting the AC power supplied from the commercial power system 30 into DC power.
In an emergency such as a power failure, the charger 16 supplies the power stored in the storage battery 15 to the locker device 20 as an emergency power source.

  The circuit switching units 17 and 18 are constituted by, for example, a relay that is controlled to be opened and closed by a control signal from the power supply control unit 11, and can switch an input source and an output destination of its own power by opening and closing the relay. It is configured to be possible.

  The circuit switching unit 17 has an input terminal connected to the DC / DC converter 13, the charger 16 and the power feeder 60, and an output terminal connected to the inverter 14, the charger 16 and the power feeder 60. For example, the solar cell 40 Is switched to output the power supplied to the storage battery 15 side or to the commercial power system 30 side (the locker device 20 side), or the power supplied from the commercial power system 30 or the solar battery 40 is supplied to the power feeder 60. Or switching whether to supply the power supplied from the power feeder 60 to the locker device 20 or the like.

  The circuit switching unit 18 has an input terminal connected to the inverter 14 and the commercial power system 30, and an output terminal connected to the commercial power system 30, the load 100, and a power output terminal 224 of the rocker device 20 described later. Whether the power supplied from the battery 40 is output to the commercial power grid 30 for sale, or is output to the power output terminal 224 of the locker device 20 as an emergency power source is switched.

The commercial power monitoring unit 101 measures a current value of power supplied from the commercial power system 30 and outputs a commercial power system measurement signal indicating the measured value to the power supply control unit 11.
When the commercial power system measurement signal is input, the power supply control unit 11 compares the measured value of the current of the commercial power system 30 indicated by the commercial power system measurement signal with the reference value of the current of the commercial power system 30. The state of power supply by the commercial power system 30 is determined based on the comparison result.
In the present embodiment, as an example, when the reference value of the current of the commercial power system 30 is 0 (A) and the absolute value of the measured value is 0 (A), the power supply control unit 11 includes the commercial power system 30. It is determined that the power supply by is stopped, and it is determined that there is power supply for other than that.
When the power supply control unit 11 determines that the power supply from the commercial power system 30 is stopped due to a power failure or the like, the power supply control unit 11 outputs a commercial power stop signal indicating the fact to the locker control unit 21 and notifies the locker device 20 side of the fact. Is notified.

The solar cell monitoring unit 102 measures the supply power value from the solar cell 40 output from the DC / DC converter 13 and outputs a solar cell measurement signal indicating the measurement value to the power supply control unit 11.
When the solar cell measurement signal is input, the power supply control unit 11 compares the measured value of the power of the solar cell 40 indicated by the solar cell measurement signal with the reference value of the power supplied to the locker device 20, and The state of power supply by the solar cell 40 is determined based on the comparison result.
For example, when the supply power value from the solar cell 40 is less than the reference value in normal times, the power supply control unit 11 supplies the insufficient power from the commercial power system 30 or the storage batteries 15 and 51 to the load 100. Let
In an emergency, when the power supply value from the solar cell 40 is less than the reference value, the power supply control unit 11 supplies the insufficient power from the storage batteries 15 and 51 to the power output terminal 224 of the locker device 20. Supply.

The storage battery monitoring unit 103 measures the storage amount of the storage battery 15 and outputs a storage battery measurement signal indicating the measured value of the storage amount to the power supply control unit 11.
When the storage battery measurement signal is input, the power supply control unit 11 compares the storage amount of the storage battery 15 indicated by the storage battery measurement signal with the reference value of the storage amount, and based on the comparison result, the storage battery 15 It is determined whether or not charging is performed.
That is, when the measured value of the storage amount of the storage battery 15 is less than the reference value, the power supply control unit 11 determines that the storage amount is insufficient and outputs a control signal to the charger 16 and the circuit switching units 17 and 18. The power is supplied to the storage battery 15 from the commercial power system 30 or the solar battery 40 via the charger 16, and charging is performed.

(3) Configuration of the locker device 20
A locker control unit 21 configured by a CPU and the like to control the operation of the entire locker device 20;
And an accommodating portion 22 that is one or more locker boxes for accommodating articles.

  When the commercial power stop signal is input from the power supply control unit 11, the locker control unit 21 recognizes that the power supply from the commercial power system 30 has stopped and unlocks the locker door 222. The unlocking signal to be output is output to the locking / unlocking unit 223.

The accommodating part 22
A storage chamber 221 which is a storage space for a box-shaped article partially opened;
A locker door 222 for sealing the opening of the storage chamber 221;
Based on the signal output from the locker control unit 21, a locking / unlocking unit 223 that locks and unlocks the locker door 222, and
A power output terminal 224 that is provided in the storage chamber 221 and includes an outlet hole or a plug and outputs power to the outside is configured.

Under normal conditions, the locker door 222 is closed and locked so as to seal the storage chamber 221 so that the power output terminal 224 in the storage chamber 221 cannot be touched by hand.
In an emergency when the power supply from the commercial power system 30 stops, when the unlocking signal is input from the locker control unit 21, the unlocking unit 223 unlocks the locker door 222 of the corresponding housing unit 22. The door can be opened and power can be supplied from the power output terminal 224 in the storage chamber 221.

FIG. 2 is an external view of the rocker device 20 according to the embodiment of the present invention.
As shown in the figure, the locker device 20 has one or more accommodating portions 22, and the locker door 222 is locked and closed by a locking / unlocking portion 223 in normal times. At this time, the power output terminal 224 is housed in the storage chamber 221 and is in a state where it cannot be connected to an external device and cannot supply power.
Therefore, it is possible to prevent troubles such as unauthorized use of power by connecting an external device to the power output terminal 224 in normal times, or mischief and damage to the power output terminal 224. .
Further, when the locker device 20 detects that the power supply from the commercial power system 30 is stopped as described above (when it is recognized that there is an emergency), the lock / unlock unit 223 unlocks the locker door 222. In addition, the door can be opened, an external device can be connected to the power output terminal 224 of the accommodation chamber 221, and power can be supplied.

(4) Configuration of Commercial Power System 30 The commercial power system 30 is a facility for supplying power from the power company to the power consumers.
The commercial power system 30 supplies power to the load 100 during normal times. Further, the commercial power system 30 supplies power to the storage battery 15 via the charger 16 for charging, or supplies power to the electric vehicle 50 (storage battery 51) via the power feeder 60 for charging. To do.

(5) Configuration of Solar Cell 40 The solar cell 40 is a device that includes a solar panel or the like, converts solar energy into electric power, and supplies the converted electric power.
The solar cell 40 normally supplies the converted power to the load 100 or sends the surplus power to the commercial power system 30 for power sale.
Further, similarly to the commercial power system 30, the solar battery 40 supplies power to the storage battery 15 via the charger 16 to charge, or powers the electric vehicle 50 (storage battery 51) via the power feeder 60. To charge the battery.
Further, in an emergency in which power supply from the commercial power system 30 is stopped, the solar cell 40 supplies power to the locker device 20 via the power supply device 10.

(6) Configuration of Electric Vehicle 50 The electric vehicle 50 is a vehicle that travels using an electric motor driven by electric power supplied from a storage battery 51 provided therein, for example, an electric vehicle, an electric motorcycle, and an electric assist bicycle. Etc.

(7) Configuration of Power Feeder 60 The power feed 60 is connected to the electric vehicle 50 and charges the storage battery 51 of the electric vehicle 50 with power supplied from the commercial power system 30 and the collection / delivery business terminal 40 via the power supply device 10. It is a device to do.

The power feeder 60 measures the amount of electricity stored in the storage battery 51 and outputs a vehicle storage battery measurement signal indicating the measured value of the amount of electricity stored to the power supply control unit 11.
When the vehicle storage battery measurement signal is input, the power supply control unit 11 compares the measured value of the storage amount of the storage battery 51 indicated by the vehicle storage battery measurement signal with the reference value of the stored amount, and based on the comparison result It is determined whether or not the storage battery 51 is charged.
That is, when the measured value of the storage amount of the storage battery 51 is less than the reference value, the power supply control unit 11 determines that the storage amount is insufficient and outputs a control signal to the power feeder 60 and the circuit switching units 17 and 18. The power is supplied to the storage battery 51 from the commercial power system 30 or the solar battery 40 via the power feeder 60, and charging is performed.

  In the event of an emergency, the power feeder 60 supplies power from the connected electric vehicle 50 storage battery 51 to the locker device 20 via the power supply device 10.

<Operation>
(1) Operation Mode of Power Supply Device 10 In the present embodiment, the power supply device 10 is powered in any of the following three modes: “interconnection operation mode”, “night mode”, and “self-sustaining operation mode”. Supply.
Among these, the interconnected operation mode and the night mode are modes that operate normally, and the self-sustained operation mode is a mode that operates in an emergency.

(2) Operation in the normal operation mode The connection operation mode is an operation mode of the power supply apparatus 10 that is applied when power generation by the solar cell 40 can be expected to some extent during normal daytime or the like. At this time, power is supplied to the load 100 from both the solar cell 40 and the commercial power system 30.

FIG. 3 is a diagram showing a current flow in the normal operation mode in the emergency power supply system according to the embodiment of the present invention.
As shown in the figure, the power supply control unit 11 is sufficient for the load 100 only from the solar cell 40 based on the solar cell measurement signal from the solar cell monitoring unit 102 in the normal interconnection operation mode. It is determined whether or not power can be supplied.

When it is determined that the power supply by the solar cell 40 is sufficient, such as in the daytime on a sunny day, the power supply control unit 11 controls the circuit switching units 17, 18, etc., from the solar cell 40 to the backflow prevention diode 12, DC DC power input to the inverter 14 via the DC / DC converter 13 and the circuit switching unit 17 is converted into AC power, and the AC power is supplied to the load 100 via the circuit switching unit 18.
In addition, the power supply control unit 11 inputs the surplus power from the solar cell 40 supplied to the load 100 to the inverter 14 via the backflow prevention diode 12, the DC / DC converter 13, and the circuit switching unit 17. After that, the inverter 14 converts the DC power into the AC power, and supplies the power to the commercial power system 30 via the circuit switching unit 18 (sells power).

  On the other hand, when it is determined that the power supply by the solar cell 40 is not sufficient, such as when it is raining or cloudy, the power supply control unit 11 controls the circuit switching units 17, 18, etc. Power is supplied to the load 100 via the backflow prevention diode 12, the DC / DC converter 13, the circuit switching unit 17, the inverter 14, and the circuit switching unit 18, and the insufficient power is supplied from the commercial power system 30 to the circuit switching unit. Power is supplied to the load 100 via 18 (purchased).

In addition, when the electric vehicle 50 (storage battery 51) is connected to the power feeder 60 and charging of the storage battery 51 of the electric vehicle 50 is requested in the interconnection operation mode, similarly, from the solar battery 40, The power is supplied to the power feeder 60 via the backflow prevention diode 12, the DC / DC converter 13, and the circuit switching unit 17.
The power feeder 60 outputs power supplied from the commercial power system 30 and the solar battery 40 to the storage battery 51 of the electric vehicle 50 for charging.
In addition, when the power supply control unit 11 determines that the power supply by the solar battery 40 is not sufficient when charging the storage battery 51 of the electric vehicle 50, the circuit switching units 17 and 18 are controlled from the solar battery 40, Power is supplied to the power feeder 60 through the backflow prevention diode 12, the DC / DC converter 13, and the circuit switching unit 17, and the insufficient power is input from the commercial power system 30 to the inverter 14 through the circuit switching unit 18. After the AC power is converted to DC power, the power is supplied to the power feeder 60 via the circuit switching unit 17.

  Further, in this interconnected operation mode, power is sufficiently supplied from the commercial power system 30 and the solar cell 40 to the load 100, so that the locker door 222 of the locker device 20 remains closed and locked, and the power output terminal 224 The emergency power supply cannot be taken.

(3) Operation in the normal night mode The night mode is an operation mode of the emergency power supply system that is applied when power generation by the solar cell 40 cannot be expected at normal time, such as at night. Power is supplied from the power system 30 to the load 100.

FIG. 4 is a diagram showing a current flow in the normal night mode in the emergency power supply system according to the embodiment of the present invention.
As shown in the figure, during the normal night mode, the power supply control unit 11 stops the operation of the DC / DC converter 13 and the inverter 14 and switches the circuit switching unit 18 so that only the circuit from the commercial power system 30 is connected. The power supply device 10 is controlled to supply power to the load 100 via the switching unit 18.

  In the night mode, when the electric vehicle 50 (storage battery 51) is connected to the power feeder 60 and charging of the storage battery 51 of the electric vehicle 50 is requested, the power supply control unit 11 Power supplied from 30 is input to the inverter 14 via the circuit switching unit 18, converted from AC power to DC power, and supplied to the power feeder 60 via the circuit switching unit 17.

  Further, even during the night mode, the power is sufficiently supplied from the commercial power system 30 to the load 100, so that the locker door 222 of the locker device 20 is kept closed and locked, and the emergency power supply is supplied from the power output terminal 224. Can not take.

(4) Charging operation in the normal operation mode or the night mode In the above operation mode or the night mode, the power supply control unit 11 uses the storage battery measurement signal from the storage battery monitoring unit 103 to When the charging amount of 15 is recognized and it is determined that the charging amount is equal to or less than a reference value, power is supplied to the charger 16 and the charging of the storage battery 15 is performed by the charger 16.
Among the above modes, in the case of the interconnected operation mode, when the power supply control unit 11 determines that the power supply amount to the load 100 and the charger 16 is sufficient only from the solar battery 40, The power supply control unit 11 causes the surplus power of the power supplied by the solar battery 40 to the load 100 to be supplied to the charger 16 and causes the charger 16 to charge the storage battery 15.
On the other hand, in the case of the interconnected operation mode, when the power supply control unit 11 determines that the surplus power supplied to the charger 16 from the solar battery 40 alone is not sufficient, the power supply control unit 11 Then, the shortage is supplied from the commercial power system 30 to the charger 16 to charge the storage battery 15 with the charger 16.
Even in the night mode, the power supply control unit 11 supplies the battery 16 to the charger 16 by supplying the charger 16 from the commercial power system 30.

FIG. 5 is a diagram showing a current flow during a normal charging operation in the emergency power supply system according to the embodiment of the present invention.
As shown in the figure, the power supplied from the solar cell 40 is input to the DC / DC converter 13 via the backflow prevention diode 12, boosted to a predetermined voltage, and then the charger 16 via the circuit switching unit 17. Is input. The charger 16 charges the storage battery 15 with the supplied supply power of the solar battery 40.
Further, as shown in the figure, the power supplied from the commercial power system 30 is input to the inverter 14 via the circuit switching unit 18, converted from AC power to DC power, and input to the charger 16. The charger 16 charges the storage battery 15 after boosting / depressing the input DC power from the commercial power system 30 to a predetermined voltage.

(5) Operation at the time of emergency self-sustained operation mode As described above, the power supply device 10 supplies power to the load 100 from the commercial power system 30 and the solar cell 40 in the “normal time”, or the solar cell 40. From the commercial power system 30 and the solar battery 40 to the storage battery 15 for charging.
On the other hand, in the “emergency time” when the power supply from the commercial power system 30 is stopped, the power supply device 10 supplies power to the locker device 20, not to the load 100 of a general electronic device or the like. Thus, it is possible to select power supply to an electronic device having a high priority.
Hereinafter, the power supply operation by the emergency power supply system in an emergency will be described.

FIG. 6 is a diagram showing a current flow in the emergency operation mode in the emergency power supply system according to the embodiment of the present invention.
As shown in the figure, when the power supply from the commercial power system 30 is stopped due to a power failure or the like, the power supplied from the solar cell 40 is input to the DC / DC converter 13 via the backflow prevention diode 12 and boosted. Later, after being input to the inverter 14 via the circuit switching unit 17 and converted from DC power to AC power, it is input to the power output terminal 224 of the rocker device 20 via the circuit switching unit 18.
In addition, when the power supplied from the solar battery 40 alone does not reach a predetermined amount of power, the power supplied from the storage battery 15 is input to the inverter 14 via the circuit switching unit 17 by the charger 16 and DC. After being converted from electric power to AC power, it is input to the power output terminal 224 of the rocker device 20 via the circuit switching unit 18.
In addition, the power supply 60 supplies power from the electric vehicle 50 to the rocker device 20 when the predetermined amount of power is not reached only by the power supplied from the solar cell 40. That is, in addition to the storage battery 15 in the power supply device 10, the storage battery 51 of the electric vehicle 50 is used as an emergency power source battery. The power supplied from the storage battery 51 of the electric vehicle 50 is input to the inverter 14 via the circuit switching unit 17 and converted from DC power to AC power, and then the power output of the rocker device 20 via the circuit switching unit 18. Input to terminal 224.

FIG. 7 is a sequence chart showing an operation flow in the emergency operation mode in the emergency by the emergency power supply system in the embodiment of the present invention.
The operation in the emergency operation mode by the emergency power supply system will be described below with reference to this figure.

First, the power supply control unit 11 determines whether or not power is being supplied from the commercial power system 30 to the power supply device 10 based on the commercial power measurement signal input from the commercial power monitoring unit 101 (step S101). ).
When it is determined that power is supplied from the commercial power system 30 (step S101 / Yes), the state where power is supplied from the commercial power system 30 and the solar cell 40 to the load 100 is maintained as usual. .

  On the other hand, when it is determined that the power supply from the commercial power system 30 is stopped (step S101 / No), the power supply control unit 11 causes a failure in the commercial power system 30 due to a power failure or the like, which is a so-called emergency. Recognize that. And the electric power supply control part 11 is based on the solar cell measurement signal input from the solar cell monitoring part 102, the storage battery measurement signal input from the storage battery monitoring part 103, and the vehicle storage battery measurement signal input from the electric power feeder 60. Then, it is determined whether or not all of the solar battery 40, the storage battery 15 and the storage battery 51 used as an emergency power supply cannot supply power (step S102).

  When it is determined that power supply from all of the solar battery 40 and the storage batteries 15 and 51 is not possible (step S102 / Yes), the operation ends because there is no power source that can be used for emergency.

On the other hand, when the power supply control unit 11 determines that power can be supplied from at least one of the solar cell 40, the storage battery 15, or the storage battery 51 (step S <b> 102 / No), the power supply control unit 11 is input from the solar cell monitoring unit 102. Based on the solar cell measurement signal, it is determined whether power can be supplied from the solar cell 40 (step S103).
When it is determined that power supply from the solar cell 40 is impossible (step S103 / No), the process proceeds to step S106 described later.

When it is determined that the power supply from the solar cell 40 is possible (step S103 / Yes), the power supply control unit 11 controls the circuit switching units 17, 18 and the like to supply power from the solar cell 40 to the locker device 20. Is supplied (step S104).
Next, the power supply control unit 11 determines whether or not the amount of power supplied from the solar cell 40 to the locker device 20 is greater than or equal to a predetermined amount of power (step S105).
When it is determined that the amount of power supplied from the solar cell 40 to the locker device 20 is sufficient (step S105 / Yes), the power supply controller 11 indicates that the power supply from the commercial power system 30 has been stopped. A stop signal is output to the rocker control unit 21 of the rocker device 20 (step S110).
When the commercial power stop signal is input from the power supply control unit 11, the locker control unit 21 of the locker device 20 outputs an unlocking signal for instructing unlocking of the corresponding locker door 222 to the locking / unlocking unit 223. To do.
When the unlocking signal is input from the locker control unit 21, the locking / unlocking unit 223 unlocks the locker door 222 and sets the lockable door unlockable state (step S <b> 111).
Thereafter, a resident of the apartment opens the corresponding locker door 222, connects an electric device to the power output terminal in the accommodation room 221, and uses the same.

  On the other hand, when electric power is supplied from the solar cell 40, but it is determined that the amount of electric power from the solar cell 40 is not sufficient to provide to the locker device 20 (step S105 / No), or solar cell When it is determined that the power is not supplied from 40 (step S103 / No), the power supply control unit 11 determines whether or not the storage battery 15 is charged based on the storage battery measurement signal input from the storage battery monitoring unit 103. Is determined (step S106).

If it is determined that the storage battery 15 has been charged (step S106 / Yes), the power supply control unit 11 turns on the charger 16, the circuit switching units 17, 18 and the like while supplying power only from the solar cell 40. Control is performed to supply power from the storage battery 15 to the locker device 20 (step S107).
At this time, when the charger 16 is configured to be able to adjust the amount of power supplied from the storage battery 15 in multiple steps, the power supply control unit 11 is based on the solar cell measurement signal from the solar cell monitoring unit 102. Then, the supply power amount that is insufficient is recognized, and the charger 16 is controlled so as to supply only the insufficient power amount from the storage battery 15.

Next, the power supply control unit 11 determines whether or not the storage battery 51 is charged based on the vehicle storage battery measurement signal input from the power feeder 60 (step S108).
Similarly, when it is determined that the storage battery 15 is uncharged (step S106 / No), the power supply control unit 11 similarly charges the storage battery 51 based on the vehicle storage battery measurement signal input from the power feeder 60. It is determined whether or not it has been performed (step S108).

When it is determined that the storage battery 51 has been charged (step S108 / Yes), the power supply control unit 11 turns on the power feeder 60, the circuit switching units 17, 18 and the like while supplying power only from the solar cell 40. The power is supplied from the storage battery 51 to the locker device 20 (step S109).
At this time, when the power supply 60 is configured to be able to adjust the amount of power supplied from the storage battery 51 in multiple steps, the power supply control unit 11 is based on the solar cell measurement signal from the solar cell monitoring unit 102. The power supply 60 is controlled so as to recognize the insufficient supply power amount and supply the shortage power amount from the storage battery 51.

Next, the power supply control unit 11 outputs a commercial power stop signal to the locker control unit 21 (step S110).
Moreover, also when it is judged that the storage battery 51 is uncharged (step S108 / No), the electric power supply control part 11 outputs a commercial power stop signal to the locker control part 21 similarly (step S110).

  When the commercial power stop signal is input from the power supply control unit 11, the locker control unit 21 outputs an unlock signal to the lock / unlock unit 223. When the unlocking signal is input from the locker control unit 21, the locking / unlocking unit 223 unlocks the locker door 222 and sets the lockable door unlockable state (step S <b> 111).

  As described above, when the power supply control unit 11 recognizes that the power supply from the commercial power system 30 has stopped, the power supply control unit 11 supplies the locker device 20 from the solar battery 40 and the storage battery 15, and the locker door 222 of the locker device 20. Since the power output terminal 224 can be used by unlocking the lock, the power output terminal 224 can be stably supplied in a common space even in an emergency, and the power output terminal 224 can be used in a normal state. It can be accommodated in 20 and protected from mischief and the like.

(6) Charging operation in the emergency operation mode in emergency mode In the emergency operation mode in emergency mode, the power supply control unit 11 receives the solar cell measurement signal from the solar cell monitoring unit 102 and the storage battery monitoring unit 103. Based on the storage battery measurement signal and the vehicle storage battery measurement signal from the power feeder 60, the amount of power supplied from the solar battery 40 and the charge amount of the storage batteries 15 and 51 are recognized, and charging the storage battery 15 by the charger 16; The charging of the storage battery 51 by the power feeder 60 is controlled.
In other words, the power supply control unit 11 is configured such that the amount of power supplied from the solar battery 40 is larger than the amount of power demand at the power output terminal of the locker device 20 and the amount of charge in the storage battery 15 is less than a predetermined amount. 16 controls the storage battery 15 to be charged with the electric power supplied from the solar battery 40.
The power supply control unit 11 is a case where the amount of power supplied from the solar battery 40 is larger than the amount of power demand at the power output terminal of the locker device 20 and the amount of charge in the storage battery 15 is less than a predetermined amount. In addition, when there is surplus power, the power feeder 60 controls the storage battery 51 to charge the surplus power supplied from the solar cell 40.
That is, the power supply control unit 11 performs control so as to charge the storage batteries 15 and 51 when there is a surplus in the amount of power supplied from the solar battery 40 and the amount of charge in the storage batteries 15 and 51 is insufficient. To do.

FIG. 8 is a diagram showing a current flow during a charging operation in an emergency in the emergency power supply system according to the embodiment of the present invention.
As shown in the figure, the power supplied from the solar cell 40 is input to the DC / DC converter 13 via the backflow prevention diode 12, boosted to a predetermined voltage, and then the charger 16 via the circuit switching unit 17. Is input. The charger 16 charges the storage battery 15 with the supplied supply power of the solar battery 40.

Furthermore, as shown in the figure, if the power supplied from the solar battery 40 is still sufficient even when the storage battery 15 is charged, the rechargeable battery 51 of the electric vehicle 50 connected to the power feeder 60 is charged. Is possible.
In this case, the power supplied from the solar cell 40 is input to the DC / DC converter 13 via the backflow prevention diode 12, boosted to a predetermined voltage, and then input to the power feeder 60 via the circuit switching unit 17. . The power feeder 60 charges the storage battery 51 with the input power supplied from the solar battery 40.

In this way, in an emergency in which the power supply from the commercial power system 30 is stopped, power is supplied from the solar cell 40 and the storage batteries 15 and 51 to the locker device 20, but the charge amount of the storage battery 15 is less than a predetermined amount. Then, in the case where the power demand of the locker device 20 can be satisfied only by the power supply from the solar battery 40, the surplus power from the solar battery 40 is charged into the storage battery 15. Furthermore, if there is surplus power even after charging the storage battery 15, the rechargeable battery 51 is charged.
Therefore, in an emergency, while satisfying the power demand at the power output terminal 224 of the locker device 20 and charging the storage batteries 15 and 51 efficiently, the power supply from the solar battery 40 such as at night cannot be expected. Stable power supply from the storage batteries 15 and 51 can be realized, and the electric vehicle 50 can be used.

<Summary of Embodiment>
As described above, according to the present embodiment, during normal times when power is supplied from the commercial power system 30, the locker door 222 of the housing portion 22 in which the power output terminal 224 is housed is locked and closed. In an emergency when the power supply from the grid 30 is stopped, the power supply device 10 supplies power to the locker device 20 from a part or all of the solar cell 40 and the storage batteries 15 and 51 and supplies the power. Since the lock of the locker door 222 of the housing portion 22 in which the power output terminal 224 is housed is unlocked, the electronic output terminal 224 is protected from mischief and unauthorized use in normal times, and is sufficient in an emergency and with a degree of freedom of application. A high emergency power supply can be stably provided in a common space.

The above-described embodiment is an example of a preferred embodiment of the present invention. The embodiment of the present invention is not limited to this, and various modifications may be made without departing from the scope of the present invention. Is possible.
For example, as described above, in the present embodiment, the accommodating portion 22 of the locker device 20 is configured to be locked / closed in a normal state and unlocked / opened in an emergency.
On the other hand, as another embodiment, it may be configured such that it is always unlocked / opened regardless of the normal time or emergency. In this case, as in the above embodiment, power can be supplied from the power output terminal 224 only in an emergency.

DESCRIPTION OF SYMBOLS 10 Power supply apparatus 11 Power supply control part 12 Backflow prevention diode 13 DC / DC converter 14 Inverter 15,51 Storage battery 16 Charger 17,18 Circuit switching part 20 Rocker apparatus 21 Rocker control part 22 Housing part 30 Commercial power system 40 Solar cell DESCRIPTION OF SYMBOLS 50 Electric vehicle 60 Electric power feeder 100 Load 101 Commercial power monitoring part 102 Solar cell monitoring part 103 Storage battery monitoring part 221 Accommodating room 222 Locker door 223 Locking / unlocking part 224 Power output terminal

Claims (6)

A power supply device for supplying commercial power in normal times,
A commercial power monitoring unit that detects the commercial power, and when the commercial power monitoring unit no longer detects the supply of the commercial power, the power supply from the commercial power is supplied from an emergency power source other than the commercial power. A power supply device that switches to power supply. An emergency power supply system comprising: the power supply device according to claim 1; and a rocker device that includes one or more storage units that are normally locked and closed and to which power is supplied by the power supply device.
In the emergency, the locker device unlocks the door of the housing portion, and can provide the power supplied from the power supply device to the outside from an outlet provided in the housing portion. Power supply system. When the commercial power monitoring unit no longer detects the commercial power supply, the power supply device outputs a commercial power abnormality signal indicating that a commercial power supply abnormality has occurred to the locker device,
When the locker device detects that the commercial power abnormality signal is input from the power supply device, the locker device unlocks the door of the housing and provides the power supplied from the power supply device to the outside. The emergency power supply system according to claim 2. A solar cell for generating electric power from solar energy as the emergency power source;
The said power supply apparatus supplies the electric power supplied from the said solar cell to the said rocker apparatus, when the said commercial power monitoring part stops detecting supply of the said commercial power. Emergency power supply system. The power supply apparatus further includes a storage battery for storing electric power as the emergency power source,
The said commercial power monitoring part supplies electric power from the said storage battery to the said locker apparatus, when it stops detecting supply of the electric power from the said commercial power, The any one of Claim 2 to 4 characterized by the above-mentioned. Emergency power supply system. An electric vehicle battery; and a power feeder connected to the battery of the electric vehicle and supplying electric power to the connected electric vehicle;
The power feeder supplies power from the battery of the connected electric vehicle to the rocker device when the commercial power monitoring unit no longer detects supply of power from the commercial power. The emergency power supply system according to any one of items 1 to 5.

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