JP2007215262A - Electrical storage system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for making regular use of an accumulator with a shallow depth of discharge and thereby lengthen the life of the accumulator. <P>SOLUTION: An electrical storage system includes: a system 10; an AC-DC inverter 11 accompanied by a controller 15; a switch 12; a power supply monitoring device 17 that monitors the state of power supply from the system 10; an lead accumulator 13; and an accumulator monitoring device 16 that monitors the state of the discharge of the accumulator 13. The electrical storage system is connected with: a load that is supplied with power from the system 10 through the AC-DC inverter 11; and a load that is supplied with power from the lead accumulator 13. According to monitoring information from the accumulator monitoring device 16 and the power supply monitoring device 17, the controller 15 controls the switch 12 so that the following is implemented: when the accumulator 13 discharges a predetermined amount, it is charged from the system 10; and when the accumulator 13 is fully charged, the accumulator 13 is discharged. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power storage system that distributes electric power using a storage battery.

  A power storage device is a device that can store electric power and extract it when necessary, and a storage battery that stores electric energy as chemical energy is known as a typical one.

Many techniques for using storage batteries have been made. For example, a method used to effectively use energy for home power storage (see Patent Document 1), or an AC power source serving as a power supply source and a DC power source can discharge power from a storage battery when the power cannot be supplied. Method (see Patent Document 2).
JP 2003-9425 A JP 2003-204682 A

  However, in these methods, the storage battery can only be used as an emergency, and since there are few opportunities to store the storage battery near full charge and discharge and use it, the deterioration of the storage battery is likely to proceed, and abnormal storage batteries It is hard to notice.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a system in which a storage battery is used at a shallow discharge depth as a regular use, thereby making the storage battery longer. This makes it possible to detect the deterioration of the storage battery as well as the life.

  According to one aspect of the present invention, a power supply connection for connecting to a power supply source, a storage battery connected to the power supply connection with the line, a first connection branched from the line, and a first connection A second connecting portion branched from the line on the power supply connecting portion side from the power supply portion, a storage battery side from the branching point to the second connecting portion on the line, and a power source from the branching point to the first connecting portion The switch means on the connection part side, a storage battery monitoring part for monitoring the discharge state of the storage battery, and a control part for controlling the switching means by monitoring information from the storage battery monitoring part, the control part from the power storage monitoring part According to the monitoring information, when it is determined that the storage battery is discharged by a predetermined amount due to the power consumption of the load connected to the first connection unit, the switch means is controlled so that the charging power is supplied from the power supply source to the storage battery. A power storage system is provided.

  Preferably, a power supply monitoring unit for monitoring a power supply state from the power supply source is further provided, and the control unit determines that the power supply from the power supply source is stopped based on monitoring information from the power supply monitoring unit Controls the switch means so that electric power is supplied from the storage battery to the load connected to the second connecting portion instead of the power supply source.

  Preferably, if the predetermined range of the total usable rated capacity of the storage battery is the first usage area, the control unit determines that power is supplied from the power supply source based on the monitoring information from the power supply monitoring unit. In this case, the switch means is controlled so that the electric power of the storage battery is consumed by the load connected to the first connection part within the range of the first use region.

  Preferably, of the usable rated capacities of the storage battery, a predetermined capacity that is larger than the first use area is referred to as a second use area, and the control unit uses the monitoring information from the power supply monitoring unit to If it is determined that the power supply has stopped, the switch means is controlled so that the power of the storage battery is consumed within the second usage area.

  Preferably, when the control unit determines from the monitoring information from the power supply monitoring unit that the power supply from the power supply source has stopped, the monitoring information from the power supply monitoring unit has priority over the monitoring information from the storage battery monitoring unit. To do.

  Preferably, when the control unit determines that the power is supplied from the power supply source based on the monitoring information from the power supply monitoring unit, and determines that the predetermined condition is satisfied, the power of the storage battery is the first. The switch means is controlled so as to be consumed by the load connected to the connecting portion.

  Preferably, a load connected to the first connection unit and continuously consuming known power is further provided, and the control unit consumes the load connected to the first use region of the storage battery and the first connection unit. Based on the time calculated from the power, the switch means is controlled so that the power of the storage battery is consumed by the load connected to the first connecting portion.

  Preferably, the monitoring information from the storage battery monitoring unit includes at least one of the voltage of the storage battery or the charge / discharge power, and the storage battery monitoring unit warns when the voltage or the charge / discharge power exceeds a predetermined range. Including means for issuing

  Preferably, the power supply source includes system power, and further includes an inverter that converts AC power from the power supply source into DC power between the power supply connection unit and the switch unit.

  Since shallow charge / discharge is always repeated, the life of the storage battery can be extended. Moreover, abnormality of a storage battery can be detected. Further, when a load having a predetermined capacity is connected, life diagnosis is possible.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

[Embodiment 1]
FIG. 1 is a block diagram showing the first embodiment.

  This embodiment will be described with reference to FIG. This system includes a connection unit 3 for connecting the system 10, an AC / DC (alternating current / direct current) inverter 11 with a control device 15, a switch 12 that is opened and closed by a control signal from the control device, and a system 10. Power supply monitoring device 17 for monitoring the power supply state of the battery, a 3 kWh lead storage battery 13, a connection unit 1 for connecting a load that consumes power from the lead storage battery 13, a storage battery monitoring device 16, and an AC / DC inverter 11 and a connecting portion 2 for connecting a load to which power is supplied via 11. In this system, the connecting unit 1 is connected to a ventilation fan 14 that consumes DC 50 W, and the connecting unit 2 is connected to a television 18 that consumes DC 100 W and an air conditioner 19 that consumes DC 900 W. By opening and closing the switch 12, the current path between the system 10 and the lead storage battery 13 and the current path between the connecting portion 2 and the lead storage battery 13 can be intermittent. The AC / DC inverter 11 is installed so that a direct current can be supplied to the lead storage battery 13, the ventilation fan 14, the television 18, and the air conditioner 19.

  System 10 is electric power from an electric power company. The AC / DC inverter 11 is a device that converts AC power into DC power. The ventilation fan 14 is a ventilation fan that has been operating for 24 hours and is a dedicated DC load that receives power from the lead storage battery 13. Here, the “dedicated DC load” of the lead storage battery 13 is a case where power is supplied from the system 10 and is a preset time zone (for example, a time when midnight power with a low power charge is supplied). Band) and the time period during which the lead storage battery 13 is charged are defined as a predetermined time period, power is supplied from the system 10 in a predetermined time period, and power is supplied from the lead storage battery 13 in a period other than the predetermined time period. DC load that receives

  The storage battery monitoring device 16 monitors the voltage and current of the lead storage battery 13, calculates the discharge power of the lead storage battery, and transmits the signal D1 to the control device 15, thereby transmitting the discharge power. In addition, the storage battery monitoring device 16 includes an alarm device that determines that the lead storage battery 13 has deteriorated and notifies the user of the deterioration by issuing an alarm or the like. The storage battery monitoring device 16 determines the deterioration by discharging all the remaining battery capacity after discharging a constant power. The remaining capacity of the storage battery may be measured periodically, and it may be determined that the lead storage battery has deteriorated when the remaining capacity falls below a certain amount. Moreover, the storage battery monitoring device 16 has built-in temperature-dependent discharge curve data that becomes a reference for deterioration when the lead storage battery 13 is discharged by the 50 W consumption ventilation fan 14, and the storage battery monitoring device 16 measures the ventilation fan 14 measured each time. A method of comparing the discharge curve with the data and judging the deterioration may be used. Since the discharge power of the lead storage battery 13 can be roughly estimated by measuring the voltage, only the voltage may be measured and judged from the estimated discharge power.

  The power monitoring device 17 monitors the voltage on the input side of the AC / DC inverter 11 and transmits a signal D2 to the control device 15 to convey the power supply state.

  The control device 15 controls the opening / closing by sending a signal D0 to the switch 12 in accordance with the signals D1 and D2.

  When the control device 15 determines that the grid 10 is supplying power based on the signal D2 from the power supply monitoring device 17 (hereinafter referred to as normal time), the lead storage battery 13 supplies power to the ventilation fan 14. Thus, an off command signal D0 is sent to the switch 12 (ON when supplying power of the system 10 to the lead storage battery 13 (or the ventilation fan 14), OFF when not). In addition, when charging the lead storage battery 13, the control device 15 outputs a signal D 0 of an on command to the switch 12. At this time, in normal operation, for example, the lead storage battery 13 is charged in a time zone in which the system power charge is low, such as late-night power, and the ventilation fan 14 is moved in the system 10, and in a time period in which the system power charge is high. It is preferable to adopt a system in which the electric power of the lead storage battery 13 is supplied to the ventilation fan 14. Moreover, the switch 12 may be turned off immediately after the lead storage battery 13 is fully charged in the system 10, and the discharge may be started. If the power charge is still low after the full charge, the power charge is high. After waiting until this time, the switch 12 may be turned off to start discharging. It is necessary to determine a condition for starting discharge as a predetermined condition.

  When the control device 15 determines that the power supply of the grid 10 is stopped based on the signal D2 from the power supply monitoring device 17 (hereinafter referred to as an emergency), a signal D0 for forcibly turning on the switch 12 is supplied. And the electric power of the lead storage battery 13 is supplied to the ventilating fan 14, the television 18, and the air conditioner 19. In addition, when the power supply monitoring device 17 detects the power supply stop of the system 10, the power of the lead storage battery 13 is supplied to the ventilation fan 14, the television 18, and the air conditioner 19 through notification means that notifies the user with sound or the like. As described above, the switch 12 may be provided with a mechanism that allows the user to manually switch the switch. In addition, by turning on the switch in front of the ventilation fan 14 and turning it to the TV 18 and the air conditioner 19 without turning the electric power to the ventilation fan 14 in an emergency, the TV 18 and the air conditioner 19 can be operated for a longer time. Good.

  In the present embodiment, the control device 15 is configured to receive power supply even in an emergency. For example, power may be supplied from the accompanying AC / DC inverter 11 by a mechanism other than the control device 15, and power may be supplied from the lead storage battery 13 in an emergency.

Next, the operation of this system will be described.
In this system, the power supply monitoring device 17 constantly monitors the voltage on the input side of the AC / DC inverter 11. For example, it confirms at intervals of 1 second and transmits the signal D2.

  The power supply monitoring device 17 sends a signal D2 indicating the power supply state from the system 10 to the control device 15, and the control device 15 determines whether the power supply is normal or emergency, and in each case the switch 12 Do different controls on. It is assumed that control device 15 preferentially controls the on command (emergency operation) based on signal D2 from power supply monitoring device 17 in an emergency over control based on other signals. For example, when an emergency signal is received during normal operation, interrupt control is performed to perform the emergency operation.

FIG. 2 is a flowchart showing the operation of the control device 15 at the normal time.
With reference to FIG. 2, the operation (normal mode) of the control device 15 at the normal time will be described first.

  The control device 15 determines whether or not the lead storage battery 13 is fully charged based on the signal D1 from the storage battery monitoring device 16 (step S206). When the battery is not fully charged (No in step S206), control device 15 issues an ON command signal D0 to switch 12, and lead storage battery 13 and ventilation fan 14 are supplied with power from system 10 (step S208). Thereby, the lead storage battery 13 is charged.

  When the battery is fully charged (Yes in step S206), control device 15 issues an off command signal D0 to switch 12, and starts discharging from lead storage battery 13 to ventilation fan 14 (step S210).

  In step S212, based on the signal D1 from the storage battery monitoring device 16, the control device 15 determines whether or not the lead storage battery 13 has been discharged by 30%. For example, the storage battery monitoring device 16 monitors the voltage and current of the lead storage battery 13 every other minute, calculates the discharge power of the lead storage battery 13, and transmits the signal D1. Here, the power usage area of the lead storage battery 13 in a normal state is referred to as a “first usage area”. In the above description, the first use area is determined to be 30% of the used rated power amount, but may be within 50% of the used rated power amount of the lead storage battery 13. The lead storage battery 13 discharges at a shallow depth of discharge (that is, in the first use region) in normal times.

  If lead-acid battery 13 of 3 kWh is 30% discharged, that is, if 900 W has not been consumed since full charge (No in step S212), control device 15 issues an off command to switch 12 so that power is continuously sent to ventilation fan 14. The signal D0 is output (step S210). Here, since the ventilation fan 14 that consumes 50 W is used, a method of calculating a time for discharging 30% capacity and starting charging after discharging may be adopted. In this case, the control device 15 outputs an off command signal D0 to the switch 12 after 900 W ÷ 50 W = 18 hours. Since the discharge power of the lead storage battery 13 can be roughly estimated by measuring the voltage, a simple method of measuring only the voltage and ending the discharge at a voltage considered to have discharged 30% of the lead storage battery capacity. You may take

  When control device 15 determines that lead storage battery 13 has been discharged 30% by signal D1 from storage battery monitoring unit 16 (Yes in step S212), power is supplied from system 10 to lead storage battery 13 and ventilation fan 14. Then, the switch 12 issues an ON command signal D0 (step S214). Note that a switch may be connected immediately before the lead storage battery 13 in order to avoid power being supplied from the system 10 even though the lead storage battery 13 is fully charged. The control device 15 controls the switch by a signal from the storage battery monitoring device 16.

  The switch may also be used when it is not desired to supply power from the grid 10 immediately after the lead storage battery 13 finishes discharging (for example, when waiting for a midnight power charge time zone with a low charge). Further, the storage battery monitoring device 16 may be configured to draw a charge / discharge curve of the lead storage battery 13 by storing the voltage or charge / discharge power and both.

The above-described operation is repeated until the end determination is made (Yes in step S216).
Next, the operation of the control device 15 in an emergency will be described.

  The power supply monitoring device 17 sends a signal D2 indicating the power supply state from the system 10 to the control device 15, and when the control device 15 determines that the power supply from the power supply is stopped, the emergency operation ( (Emergency mode).

FIG. 3 is a flowchart showing the operation of the control device 15 in an emergency.
With reference to FIG. 3, the operation of the control device 15 in an emergency will be described.

  In step S300, the control device 15 outputs an ON command signal D0 to the switch 12 so that power is supplied from the lead storage battery 13 to the television 18, the air conditioner 19, and the ventilation fan 14. Here, the power usage area of the lead storage battery 13 in an emergency is referred to as a “second usage area”. In the second use area, the entire usable rated capacity may be used, or a predetermined capacity such as 90% of the usable rated capacity may be set. However, it is assumed that the second use area is larger than the first use area.

  If control device 15 determines that power supply from system 10 is stopped based on signal D2 from power supply monitoring device 17 (No in step S302), power supply from the lead storage battery is continued (step S300). If controller 15 determines that the power supply from system 10 has been restored (Yes in step S302), switch 12 is turned on so that power is supplied from system 10 to lead storage battery 13 and ventilation fan 14. The signal D0 is output (step S304). As a result, the lead storage battery 13 is charged. If lead storage battery 13 is fully charged, the emergency mode is terminated (Yes in step S306).

  According to the above description, it is possible to repeat shallow charging / discharging for the storage battery at all times. Therefore, the life of the storage battery is extended and deterioration is easily detected. Moreover, since the storage battery is used in the same way every time, the life of the storage battery can be predicted.

[Embodiment 2]
FIG. 4 is a block diagram showing the second embodiment.

  The second embodiment will be described with reference to FIG. In addition to the configuration of the first embodiment, the power storage system in the second embodiment further includes a switch 42 that intermittently connects the current path between the lead storage battery 13 and the ventilation fan 14.

  The control device 15 is set in advance with a time zone for late-night power and is stored in a memory or the like. Thereby, in the normal mode, the control device 15 controls the switch 12 and the switch 42 so that the lead storage battery 13 is charged in the midnight time zone. In the present embodiment, midnight to 7:00 am is a time zone for late-night power.

  FIG. 5 is a diagram showing the operation of the second embodiment from 7:00 am on September 27 to 7:00 am on September 29 in time series.

A specific operation of the second embodiment will be described with reference to FIG.
At 7:00 am (t1) on September 27, power is supplied from the grid 10 (P1). As a result, power is supplied from the system 10 to the television 18 and the air conditioner 19. The lead storage battery 13 is fully charged, and the control device 15 sends an off command signal D0 to the switch 12 and an on command signal D3 to the switch 42 by the signal D1 from the storage battery monitoring device 16. Therefore, the electric power of the lead storage battery 13 is supplied to the ventilation fan 14 (S11).

  At 1 am (t2) on September 28, 30% of the capacity of the lead storage battery 13 is discharged. The control device 15 senses this by the signal D1 of the storage battery monitoring device 16, and sends an on-command signal D0 to the switch 12 because 1:00 am is also a time zone of midnight power. Therefore, electric power is supplied from the system 10 to the lead storage battery 13 and the ventilation fan 14. Thereby, the lead storage battery 13 is charged (S12). Six hours later, the state continues until 7:00 am (t3) on September 28, and the lead storage battery 13 is fully charged. The control device 15 senses the signal D1 from the storage battery monitoring device 13 and sends an off command signal to the switch 12. The lead storage battery 13 is operated as it is from 7 o'clock in the morning on September 27 (t1) (S11). When the power supply from the system 10 stops at 2:00 pm (t4) on September 28 (P2), the control device 15 detects this by the signal D2 of the power supply monitoring device 17, and instructs the switch 12 to forcibly turn on. The signal D0 is sent. Thereby, the electric power of the lead storage battery 13 is sent to the ventilation fan 14, the television 18, and the air conditioner 19 (S13). At 3:00 p.m. (t5) on September 28, the power supply is restored from the system 10 (P1), and the control device 15 senses this by the signal D2 from the power supply monitoring device 17. At this time, the capacity of the lead storage battery 13 is reduced to 50%, and the control device 15 is operating in the emergency mode, so that the switch 12 remains on and the system 10 is connected to the lead storage battery 13, the ventilation fan 14, and the television 18 And power is supplied to the air conditioner 19. Thereby, the lead storage battery 13 is charged (S12). At 1:00 am (t6) on September 29, the lead storage battery 13 is fully charged, but because of the late-night power hours, the control device 15 issues a signal of an off command to the switch 42 as previously set. The system 10 supplies power to the ventilation fan 14, the television 18, and the air conditioner 19. Meanwhile, the lead storage battery 13 does not supply any power (S14). From 7:00 am (t7) on September 29, when the midnight power period ends, the control device 15 sends an on-command signal D3 to the switch 42 and an off-command signal D0 to the switch 12, and the lead storage battery 13 Performs the same operation as on September 27 (S11).

  According to the above description, in addition to being able to repeat shallow charging / discharging to / from the storage battery at all times, it is possible to use inexpensive power by controlling the switch 42 so as to use midnight power. Therefore, in addition to the effects of the first embodiment, the user can enjoy an economic merit.

[Embodiment 3]
FIG. 6 is a block diagram showing the third embodiment.

  The third embodiment will be described with reference to FIG. The power storage system in the third embodiment includes a bidirectional AC / DC inverter 61 and a switch 62 instead of the AC / DC inverter 11 in the configuration of the second embodiment. Note that, instead of a bidirectional AC / DC inverter, an AC / DC inverter and a DC / AC inverter may be connected in parallel one by one. Further, instead of the television 18 and the air conditioner 19, an AC 200 W-consuming refrigerator 68 is connected and supplied with power from the system 10. The switch 62 interrupts the current path between the system 10 and the bidirectional AC / DC inverter 61 by the control signal D4 from the control device 15. Further, in the control device 15, a time zone for midnight power is set as in the second embodiment and stored in a memory or the like. The functions of the other components are the same as in the second embodiment.

  FIG. 7 is a diagram showing the operation of the third embodiment from 7:00 am on September 27 to 7:00 am on September 29 in time series.

With reference to FIG. 7, the operation of this system will be specifically described.
Initially, the switch 12, the switch 42, and the switch 62 are in an on state. At 7:00 am (t1) on September 27, the grid 10 supplies power (P1). Thereby, AC power is supplied to the refrigerator 68 from the system 10. The lead storage battery 13 is fully charged. The control device 15 detects the signal D1 from the storage battery monitoring device 16 and sends an off command signal D0 to the switch 12. Thereby, the electric power of the lead storage battery 13 is supplied to the ventilation fan 14 (S11). At 1 am (t2) on September 28, 30% of the capacity of the lead storage battery 13 is discharged. The control device 15 senses it based on the signal D1 from the storage battery monitoring device 16, and sends an ON command signal D0 to the switch 12 because it is a time zone of midnight power. Therefore, electric power is supplied from the system 10 to the lead storage battery 13 and the ventilation fan 14, whereby the lead storage battery 13 is charged (S12). At 7:00 am (t3) on September 28, the lead storage battery 13 is fully charged, and the control device 15 senses this by the signal D1 from the storage battery monitoring device 16 and supplies the switch 12 with an off command signal D0. Send. The lead storage battery 13 operates in the same manner as from 7 am on September 27 (S11). When the power supply from the system 10 stops at 2:00 p.m. (t4) on September 28 (P2), the control device 15 detects this by the signal D2 from the power supply monitoring device 17 and forcibly turns on the switch 12. A command signal D0 is sent, and a forced-off command signal D4 is sent to the switch 62. The electric power of the lead storage battery 13 is sent to the refrigerator 68 via the ventilation fan 14 and the bidirectional AC / DC inverter 61 (S13). At 3:00 p.m. (t5) on September 28, the power supply from the grid 10 is restored (P1), and the power supply monitoring device 17 sends a signal D2 to the control device 15. Based on this, the control device 15 switches the switch 62. The signal D4 of the on command is sent to The system 10 supplies power to the lead storage battery 13, the ventilation fan 14, and the refrigerator 68. Thereby, the lead storage battery 13 is charged (S12). At 1:00 am (t6) on September 29, the lead storage battery 13 is fully charged, but since it is a time zone of late-night power input in advance to the control device 15, the control device 15 instructs the switch 42 to turn off. The signal D3 is output, and the system 10 supplies power to the ventilation fan 14 and the refrigerator 68. The lead storage battery 13 does not supply any power (S14). From 7:00 am (t7) on September 29, when the midnight power time period ends, the control device 15 issues an off command signal D0 to the switch 12, an on command signal D3 to the switch 42, and the lead storage battery 13 The same operation as on September 27 is performed (S11).

  Although this embodiment has only an AC load, a system having both an AC load and a DC load, which is a combination of the second and third embodiments, may be used.

  According to the above description, in addition to being able to repeat shallow charging / discharging to / from the storage battery at all times, it is possible to use inexpensive power by controlling the switch 42 so as to use midnight power. Therefore, also in the present embodiment, the same effect as in the third embodiment can be obtained.

[Embodiment 4]
FIG. 8 is a block diagram showing the fourth embodiment.

  The system includes a connection unit 3 for connecting to a power supply source, a lithium ion secondary battery 83, a connection unit 1 for connecting a load that consumes power from the lithium ion secondary battery 83, and a power supply. Connection unit 2 for connecting a load that receives power supply from the power source, switch 12, storage battery monitoring device 16 for monitoring the discharge state of the lithium ion secondary battery 83, and power supply state from the power supply source The power supply monitoring device 87 for monitoring the power supply and the control device 85 for controlling the switch 12 are provided. The connecting portion 1 includes a fluorescent lamp 84 that consumes 50 W DC, the connecting portion 2 includes the television 18 and the air conditioner 19 as in the first embodiment, and the connecting portion 3 includes a fuel cell 80 as a power supply source. Is connected. Further, by opening / closing the switch 12, the current path between the fuel cell 80 and the lithium ion secondary battery 83 and the current path between the fuel cell 80 and the fluorescent lamp 84 can be interrupted.

  The control device 85 has the same function as the control device 15 and is supplied with power from the lithium ion secondary battery 83.

  The power supply monitoring device 17 monitors whether or not the output voltage from the fuel cell is applied, and transmits the signal D2 to the control device 85 to transmit the monitoring information.

  Instead of the fuel cell 80, the connection unit 3 may be a system and an AC / DC inverter that converts AC power from the system into DC power.

Since the specific operation of this system is the same as that of the first embodiment, it will not be repeated.
Here, even if the fuel cell 80 is operated in a steady state, the fuel cell 80 may be connected to the connection portion 3 via the load required power measurement facility and operated according to the load request.

  The lithium ion secondary battery 83 is more suitable for this system than a system using a lead-acid battery because the effect of extending the life by performing shallow charge / discharge is high.

  The fluorescent lamp 84 may be lit only at night, may be supplied from the lithium ion secondary battery 83 at night, and may be supplied from the fuel cell 80 during the day, or according to the power charge of the fuel cell 80 or the like. It is preferable to make the system less expensive.

  According to the above description, it is possible to repeat shallow charging / discharging for the storage battery at all times. Therefore, also in the present embodiment, the same effect as in the first embodiment can be obtained.

[Embodiment 5]
FIG. 9 is a block diagram showing the fifth embodiment.

The fifth embodiment will be described with reference to FIG.
The power storage system in the fifth embodiment is connected to the solar cell 90, the system 10, and the system 10 instead of the fuel cell 80 in the configuration of the fourth embodiment, and converts AC power from the system 10 into DC power. An AC / DC inverter 11 is connected to the connection unit 3 in parallel. The configuration other than the fuel cell 80 is the same.

  The amount of power generated by the solar cell 90 is the total amount of power consumed by the fluorescent lamp 84 connected to the connection unit 1, the television 18 connected to the connection unit 2, and the air conditioner 19 (hereinafter referred to as total power consumption amount). Is larger than), the power of the solar cell 90 is supplied to the connecting portion 3. Surplus power (a value obtained by subtracting the total power consumption from the power generation amount) is sold to the grid 10.

  When the power generation amount of the solar cell 90 is smaller than the total power consumption, the power of the solar cell 90 is supplied to the connection unit 3. Insufficient power (a value obtained by subtracting the power generation amount of the solar cell 90 from the total power consumption) is supplied from the system 10 to the connection unit 3.

  Since such a system is a general method taken by the current solar cell system, detailed description is omitted.

  Since the specific operation of the present embodiment is the same as that of the first embodiment, it will not be repeated. At present, the late-night electricity rate is cheaper than the electricity sale rate of the electricity generated by the solar cell 90. Therefore, power is supplied to the lithium ion secondary battery 83 and the fluorescent lamp 84 at night, and the generated electricity of the solar cell 90 during the daytime. It is also possible to sell power to the grid 10. In general, a solar cell system is provided with a divergence switch in order to prevent the power of the solar cell from flowing backward to the grid. In the event of a power failure, if the solar cell system control unit that controls the deviation switch and the power supply monitoring device 17 are linked, reverse power flow can be prevented more. Moreover, in order to prevent the abnormal rise of the voltage in a system | strain, a normal solar cell system may restrict | limit the output of a solar cell. In that case, in order not to waste the surplus power of the solar cell 90, the control device 15 may receive an output restriction signal from the solar cell system and turn on the switch 12.

  According to the above description, it is possible to repeat shallow charging / discharging for the storage battery at all times. Therefore, also in the present embodiment, the same effect as in the first embodiment can be obtained.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1 is a block diagram showing a first embodiment. It is a flowchart showing operation | movement of the control apparatus 15 at the normal time. It is a flowchart showing operation | movement of the control apparatus 15 in emergency. FIG. 6 is a block diagram showing a second embodiment. It is the figure which represented the operation | movement from 7:00 am of September 27 to 7:00 am of September 29 of Embodiment 2 in time series. FIG. 6 is a block diagram showing a third embodiment. It is the figure which represented the operation | movement from 7:00 am of September 27 to 7:00 am of September 29 of Embodiment 3 in time series. FIG. 10 is a block diagram showing a fourth embodiment. FIG. 10 is a block diagram showing a fifth embodiment.

Explanation of symbols

  1, 2, 3 connections, 10 systems, 11 AC / DC inverters, 12, 42, 62 switches, 13 lead storage batteries, 14 ventilation fans, 15, 85 control devices, 16, 86 storage battery monitoring devices, 17, 87 power supply monitoring devices 18 TV, 19 Air conditioner, 61 Bidirectional AC / DC inverter, 68 Refrigerator, 80 Fuel cell, 83 Lithium ion secondary battery, 84 Fluorescent lamp, 90 Solar cell.

Claims (9)

A power connection for connecting to a power supply;
A storage battery connected by a power line and a power line,
A first connecting portion branched from the line;
A second connecting portion branched from the line on the power supply connecting portion side from the first connecting portion;
Switch means on the storage battery side from the branch point to the second connection part on the line and on the power supply connection side from the branch point to the first connection part;
A storage battery monitoring unit for monitoring the discharge state of the storage battery;
A control unit for controlling the switch means by monitoring information from the storage battery monitoring unit,
The controller is
When it is determined from the monitoring information from the power storage monitoring unit that the storage battery has been discharged by a predetermined amount due to power consumption of the load connected to the first connection unit, charging power is supplied from the power supply source to the storage battery. A power storage system for controlling the switch means to be supplied. A power supply monitoring unit for monitoring a power supply state from the power supply source;
The controller is
If it is determined from the monitoring information from the power supply monitoring unit that power supply from the power supply source has stopped, power is supplied from the storage battery to the load connected to the second connection unit instead of the power supply source. The power storage system according to claim 1, wherein the switch unit is controlled so that the power is supplied. Of the entire usable rated capacity of the storage battery, when the predetermined range is the first use area,
The controller is
When it is determined from the monitoring information from the power supply monitoring unit that power is being supplied from the power supply source, the power of the storage battery is within the range of the first use region. The power storage system according to claim 2, wherein the switch unit is controlled so as to be consumed by a load connected to. Among the usable rated capacities of the storage battery, a predetermined capacity that is larger than the first use area is referred to as a second use area,
The controller is
When the monitoring information from the power supply monitoring unit determines that the power supply from the power supply source has stopped, the switch is configured so that the power of the storage battery is consumed within the range of the second usage region. The electrical storage system of Claim 3 which controls a means. The controller is
If it is determined by the monitoring information from the power supply monitoring unit that power supply from the power supply source has stopped, the monitoring information from the power supply monitoring unit has priority over the monitoring information from the storage battery monitoring unit. The power storage system according to any one of claims 2 to 4. The controller is
According to the monitoring information from the power supply monitoring unit, when it is determined that power is being supplied from the power supply source, and when it is determined that a predetermined condition is satisfied, the power of the storage battery is the first connection The power storage system according to any one of claims 2 to 5, wherein the switch unit is controlled so as to be consumed by a load connected to the unit. A load connected to the first connection and continuously consuming known power;
The controller is
Based on the time calculated from the first usage area of the storage battery and the power consumption of the load connected to the first connection, the power of the storage battery is connected to the first connection. The power storage system according to claim 3, wherein the switch unit is controlled so as to be consumed by a different load. The monitoring information from the storage battery monitoring unit includes at least one of the voltage of the storage battery or charge / discharge power,
The power storage system according to any one of claims 1 to 7, wherein the storage battery monitoring unit includes means for issuing a warning when the voltage or the charge / discharge power is determined to have exceeded a predetermined range. . The power supply source includes grid power,
The power storage system according to any one of claims 1 to 8, further comprising an inverter that converts AC power from the power supply source into DC power between the power supply connection unit and the switch unit.

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