JP2011083057A - Storage battery residual capacity monitoring device for power supply system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a storage battery residual capacity monitoring device for a power supply system, capable of improving accuracy in detecting the residual capacity of a storage battery. <P>SOLUTION: A plurality of storage batteries 43a, 43b are mounted on a storage battery unit 16. When for example, the first storage battery 43a as a backup power supply performs a discharging operation, a discharging speed detection section 57 calculates a discharging speed of the first storage battery 43a. A storage battery residual capacity monitoring section 59 compares the discharging speed with a threshold value thereof, and if the discharging speed becomes not more than the threshold value, the monitoring section 59 recognizes that the residual capacity of the first storage battery 43a is small. At this time, a power supply switching section 60 switches the backup power supply from the first storage battery 43a which has been used so far to the second storage battery 43b to continuously supply power to a load. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a storage battery remaining amount monitoring device for a power supply system that monitors the remaining battery capacity of a storage battery that is one power source of a power supply system.

  A home is provided with a power supply system (see Patent Document 1 or the like) that converts an AC voltage of a commercial power source into a DC voltage and supplies it to various devices in the house. In recent power supply systems, solar cells that generate power by solar power generation are provided, and not only commercial power sources but also solar cells capable of generating DC power for various devices have begun to spread. In addition, some power supply systems have a storage battery as a backup power source for the system. The storage battery can be used for the commercial power supply at low cost and the power that can be generated by extra sunlight during the day. It can be stored.

JP 2009-159690 A

  By the way, in this type of storage battery, the remaining amount of the battery decreases as it is consumed. Therefore, when the remaining amount of voltage is low, the amount of stored power is reduced. You have to switch to enough other batteries. Therefore, this type of power supply system needs to be equipped with a function for more accurately monitoring the remaining battery level of the storage battery in order to see the optimal switching timing of the storage battery. For this reason, development of the technique which can see the battery remaining amount of a storage battery more correctly was requested | required.

  The objective of this invention is providing the storage battery residual amount monitoring apparatus of the electric power supply system which can improve the detection accuracy of the battery residual amount of a storage battery.

  In order to solve the above problems, in the present invention, the voltage obtained from a system or a stand-alone power generation battery is converted into a voltage while the voltage is branched and supplied to each load, and the power supply for backup of the system or the stand-alone power generation battery is provided. In the storage battery remaining amount monitoring device of the power supply system equipped with a storage battery as a discharge rate detection means for detecting a discharge rate under a constant current of the storage battery, and comparing the discharge rate with its threshold value, The gist is provided with a storage battery remaining amount monitoring means for monitoring the amount.

  According to this configuration, the remaining speed of the storage battery is monitored by monitoring the discharge speed (voltage change amount) of the storage battery and comparing the discharge speed with the threshold value. By the way, in the storage battery, there is a tendency that the discharge rate is greatly reduced immediately before the remaining battery level is exhausted. Therefore, when the discharge speed of the storage battery is greatly reduced, it is determined that the remaining amount of the storage battery is small, and the power source is switched to another power source, for example. For this reason, it is possible to determine whether or not the storage battery has reached the lower limit remaining amount in a highly accurate form of a change in the discharge speed of the storage battery.

As a definition, “under a constant current” is a value having a width including that the current value fluctuates to some extent as long as the discharge rate can be detected.
The gist of the present invention is that power supply switching means is provided for switching the power supply of the load to another storage battery when the discharge speed becomes equal to or less than the threshold value.

  According to this configuration, when the remaining amount of the storage battery becomes small, the storage battery is switched to another storage battery. Therefore, even if the remaining amount of the storage battery decreases, power can be continuously supplied to the load. It becomes possible.

  In the present invention, a discharge capacity integrating means for integrating the discharge current from the full charge of the storage battery, and a storage battery capacity calculating means for calculating the usable capacity of the storage battery from the integrated value of the discharge capacity integrating means are provided. The gist.

  According to this configuration, the usable capacity of the storage battery is calculated by integrating the discharge current from the full charge of the storage battery, so in addition to accurately seeing the lower limit remaining capacity of the storage battery, the usable capacity of the storage battery must also be grasped Is possible.

  In the present invention, the load is a constant current load that is controlled by itself so that the discharge current is constant, and the discharge rate is a discharge rate generated when electric power is discharged to the constant current load. The gist.

According to this configuration, since a constant current load is used as the load, the remaining amount of the storage battery can be detected with higher accuracy.
In the present invention, a constant current load that changes the voltage of the storage battery at a constant current during discharge is another storage battery that is not used as a power source to the load, and the discharge speed is to the other battery. The gist is that it is a discharge rate at the time of discharging.

  According to this configuration, the other storage battery is a load that actually consumes energy during operation. However, if the discharge speed of the storage battery is detected using such a load, the storage battery can be reduced with less energy loss. It is possible to detect the remaining battery level.

  In the present invention, a charging capacity integrating unit that integrates a charging current when charging the storage battery, and a storage battery capacity calculating unit that calculates a usable capacity of the storage battery from an integrated value of the charging capacity integrating unit are provided. The gist.

According to this configuration, the usable capacity of the storage battery can be calculated by integrating the charging current.
In the present invention, discharge capacity integration means for integrating the discharge current from full charge of the storage battery, charge capacity integration means for integrating charge current when charging the storage battery, integrated value of the discharge capacity integration means, The gist is provided with storage battery capacity calculation means for calculating the usable capacity of the storage battery from an average value with the integrated value of the charge capacity integration means.

  According to this configuration, since the remaining amount of the storage battery is calculated based on the average value of the integrated value of the discharge current at the time of discharging and the integrated value of the charging current of the charge value, the usable capacity of the storage battery is specified more accurately. It becomes possible.

  ADVANTAGE OF THE INVENTION According to this invention, the detection precision of the battery remaining charge of a storage battery can be improved.

The block diagram which shows the structure of the electric power supply system in 1st Embodiment. The block diagram which shows the structure of a battery remaining charge monitoring system. The wave form diagram which shows the change of the discharge voltage of a storage battery. (A)-(d) is explanatory drawing which shows the use process of a storage battery. (A)-(d) is explanatory drawing which shows the use process of the storage battery in 2nd Embodiment.

(First embodiment)
Hereinafter, a first embodiment in which a storage battery remaining amount monitoring device of a power supply system of the present invention is embodied in a house will be described with reference to FIGS.

  As shown in FIG. 1, a house is provided with a power supply system 1 that supplies power to various devices (such as lighting devices, air conditioners, home appliances, and audiovisual devices) installed in the house. The power supply system 1 operates various devices using commercial AC power (AC power) obtained from the system 2 as power, and also supplies the power of the solar cell 3 generated by sunlight as power to various devices. The solar cell 3 is composed of, for example, a plurality of cells 4. The power supply system 1 supplies power not only to the DC device 5 that operates by inputting a DC power supply (DC power supply) but also to the AC device 6 that operates by inputting an AC power supply (AC power supply). The solar cell 3 corresponds to a self-supporting power generation battery, and the DC device 5 and the AC device 6 constitute a load.

  The power supply system 1 is provided with a control unit 7 and a DC distribution board (built-in DC breaker) 8 as a distribution board of the system 1. The power supply system 1 is provided with a control unit 9 and a relay unit 10 as devices for controlling the operation of the DC device 5 in the house.

  An AC distribution board 11 for branching an AC power supply is connected to the control unit 7 via an AC power line 12. The control unit 7 is connected to the system 2 through the AC distribution board 11 and is connected to the solar cell 3 through the DC system power line 13. The control unit 7 takes in AC power from the AC distribution board 11 and DC power from the solar cell 3 and converts these powers into predetermined DC power as a device power source. Then, the control unit 7 outputs the converted DC power to the DC distribution board 8 via the DC system power line 14 or outputs it to the storage battery unit 16 via the DC system power line 15. To store electricity. The control unit 7 can not only take AC power from the AC distribution board 11 but also convert the power of the solar cell 3 and the storage battery unit 16 to AC power and supply it to the AC distribution board 11. The control unit 7 exchanges data with the DC distribution board 8 via the signal line 17.

  The DC distribution board 8 is a kind of breaker that supports DC power. The DC distribution board 8 branches the DC power input from the control unit 7 and outputs the branched DC power to the control unit 9 via the DC power line 18 or relays via the DC power line 19. Or output to the unit 10. Further, the DC distribution board 8 exchanges data with the control unit 9 through the signal line 20 and exchanges data with the relay unit 10 through the signal line 21.

  A plurality of DC devices 5, 5... Are connected to the control unit 9. These DC devices 5 are connected to the control unit 9 via a DC supply line 22 that can carry both DC power and data by a pair of lines. The DC supply line 22 superimposes a communication signal for transmitting data by a high-frequency carrier wave on a DC voltage serving as a power source for the DC device, so-called power line carrier communication. Transport to. The control unit 9 acquires the DC power supply of the DC device 5 via the DC power line 18 and controls which DC device 5 based on the operation command obtained from the DC distribution board 8 via the signal line 20. Know what to do. Then, the control unit 9 controls the operation of the DC device 5 by outputting a DC voltage and an operation command to the instructed DC device 5 via the DC supply line 22.

  A switch 23 that is operated when switching the operation of the DC device 5 in the house is connected to the control unit 9 via a DC supply line 22. In addition, a sensor 24 that detects a radio wave transmitted from an infrared remote controller, for example, is connected to the control unit 9 via a DC supply line 22. Therefore, not only the operation instruction from the DC distribution board 8 but also the operation of the switch 23 and the detection of the sensor 24, a communication signal is sent to the DC supply line 22 to control the DC device 5.

  A plurality of DC devices 5, 5... Are connected to the relay unit 10 via individual DC power lines 25. The relay unit 10 acquires the DC power supply of the DC device 5 through the DC power line 19 and determines which DC device 5 is to be operated based on an operation command obtained from the DC distribution board 8 through the signal line 21. To grasp. The relay unit 10 controls the operation of the DC device 5 by turning on / off the power supply to the DC power line 25 with respect to the instructed DC device 5 using a built-in relay. Further, the relay unit 10 is connected to a plurality of switches 26 for manually operating the DC device 5, and the DC power line 25 is turned on / off by the relay by operating the switch 26, so that the DC The device 5 is controlled.

  The DC distribution board 8 is connected to a DC outlet 27 built in a house in the form of a wall outlet or a floor outlet, for example, via a DC power line 28. If a plug (not shown) of a DC device is inserted into the DC outlet 27, DC power can be directly supplied to the device.

  Further, a power meter 29 capable of remotely measuring the amount of use of the system 2 is connected between the system 2 and the AC distribution board 11. The power meter 29 is equipped with not only a function of remote meter reading of the amount of commercial power used, but also a function of power line carrier communication and wireless communication, for example. The power meter 29 transmits the meter reading result to an electric power company or the like via power line communication or wireless communication.

  The power supply system 1 is provided with a network system 30 that enables various devices in the home to be controlled by network communication. The network system 30 is provided with a home server 31 as a control unit of the system 30. The home server 31 is connected to a management server 32 outside the home via a network N such as the Internet, and is connected to a home device 34 via a signal line 33. The in-home server 31 operates using DC power acquired from the DC distribution board 8 via the DC power line 35 as a power source.

  A control box 36 that manages operation control of various devices in the home by network communication is connected to the home server 31 via a signal line 37. The control box 36 is connected to the control unit 7 and the DC distribution board 8 via the signal line 17 and can directly control the DC device 5 via the DC supply line 38. For example, a gas / water meter 39 capable of remotely metering the amount of gas used or the amount of water used is connected to the control box 36 and also connected to the operation panel 40 of the network system 30. The operation panel 40 is connected to a monitoring device 41 including, for example, a door phone slave, a sensor, and a camera.

  When the in-home server 31 inputs an operation command for various devices in the home via the network N, the home server 31 notifies the control box 36 of the instruction, and operates the control box 36 so that the various devices operate in accordance with the operation command. . The in-home server 31 can provide various information acquired from the gas / water meter 39 to the management server 32 through the network N, and accepts from the operation panel 40 that the monitoring device 41 has detected an abnormality. This is also provided to the management server 32 through the network N.

  As shown in FIG. 2, the control unit 7 is provided with a DC / DC converter 42 connected to the solar cell 3. The DC / DC converter 42 converts the DC voltage from the solar cell 3 into a predetermined value, and outputs the converted DC voltage to the DC distribution board 8 and the storage battery unit 16. The DC power output to the DC distribution board 8 is supplied to the DC device 5 as a device power source. Further, the DC power output to the storage battery unit 16 is stored in a plurality of storage batteries 43, 43. In this example, one of the two storage batteries 43, 43 is a first storage battery 43a and the other is a second storage battery 43b.

  The control unit 7 is provided with a bidirectional AC / DC converter 44 connected to the AC distribution board 11. The bidirectional AC / DC converter 44 converts the AC power acquired from the system 2 into DC power and outputs the DC power to the DC distribution board 8 or the storage battery unit 16. Conversely, for example, the DC power acquired from the solar cell 3. The power is converted into AC power and supplied to the AC distribution board 11.

  A DC / DC converter 45 connected to the DC / DC converter 42 and the bidirectional AC / DC converter 44 is connected to the DC distribution board 8. The DC / DC converter 45 converts the DC voltage acquired from the control unit 7 into a predetermined value, and outputs it to the various DC devices 5 via the breakers 46, 46.

  The storage battery unit 16 is provided with a DC / DC converter 47 that converts a DC voltage input and output in the unit 16 into a predetermined value. When the DC / DC converter 47 charges the storage batteries 43,... With the DC voltage input from the control unit 7, the DC / DC converter 47 converts this voltage into a predetermined value or outputs the DC voltage of the storage batteries 43,. In this case, the voltage is converted into a predetermined value. Further, the DC / DC converter 47 can appropriately switch the discharge current Ih flowing therethrough based on the input voltage.

  The power supply system 1 is provided with a battery remaining amount monitoring system 1a for monitoring the remaining battery amount of the storage battery 43 in use. The battery remaining amount monitoring system 1a of this example calculates the discharge rate K of the storage battery 43 in use, and compares the discharge rate K with its threshold value Kr, so that the remaining amount of the storage battery 43 reaches the lower limit remaining amount. Monitor whether or not. Then, when the discharge rate K of the storage battery 43 in use decreases below the threshold value Kr, the battery remaining amount monitoring system 1a recognizes that the storage battery 43 has become low and switches the power source to another storage battery 43.

  In this case, a first opening / closing switch 49 for turning on / off the connection of these two members is connected on the path of the wiring 48 connecting the DC / DC converter 47 and the first storage battery 43a. The wiring 48 is provided with a first storage battery current detection unit 50 that detects a current flowing into and out of the first storage battery 43a, and a first storage battery voltage detection unit 51 that detects a voltage of the first storage battery 43a.

  In addition, a second opening / closing switch 53 for turning on / off the connection between the two members is connected on the path of the wiring 52 that connects the DC / DC converter 47 and the second storage battery 43b. The wiring 52 is provided with a second storage battery current detection unit 54 that detects a current flowing into and out of the second storage battery 43b, and a second storage battery voltage detection unit 55 that detects a voltage of the second storage battery 43b.

  The storage battery unit 16 is provided with a state detection determination control unit 56 that monitors the remaining battery capacity of a storage battery in use as a backup power source among the plurality of storage batteries 43. The state detection determination control unit 56 is provided with a discharge rate detection unit 57 that detects the discharge rate of the storage battery 43. The discharge rate detection unit 57 calculates the discharge rate K1 of the first storage battery 43a by obtaining the amount of change per unit time of the voltage obtained from the first storage battery voltage detection unit 51. That is, when the voltage of the first storage battery 43a is V and the time is t, the discharge speed K1 is obtained by ΔV / Δt which is the slope of the voltage waveform as shown in FIG. The discharge speed detection unit 57 can also calculate the discharge speed K2 of the second storage battery 43b by the same method as that for the first storage battery 43a. The discharge speed detection unit 57 corresponds to a discharge speed detection unit.

  Here, when the discharge rate K of the storage battery 43 is calculated, if the discharge current Ih changes, the discharge voltage also changes according to this change, so that an accurate discharge rate according to the remaining amount of the storage battery 43 is obtained. K cannot be calculated. Therefore, in the case of this example, a constant current load 58 (see FIG. 4) is used as a device to which power is supplied. The constant current load 58 is a load that is controlled by itself so that the discharge current Ih is constant. The constant current load 58 constitutes a load.

  As shown in FIG. 2, the state detection determination control unit 56 is provided with a storage battery remaining amount monitoring unit 59 that monitors the remaining amount of the storage battery 43 based on the discharge speed K. By the way, as shown in FIG. 3, when the remaining amount of the battery 43 is the lower limit remaining amount, that is, the remaining amount is little, the discharge rate K is greatly reduced. It is known that the efficiency decreases. Therefore, the storage battery remaining amount monitoring unit 59 compares the discharge rate K with the threshold value Kr to see whether or not the discharge rate K has a value equal to or less than the threshold value Kr. And the storage battery residual amount monitoring part 59 recognizes that the storage battery 43 became low, when the discharge speed K became the threshold value Kr or less. The lower limit remaining amount is a value that falls into a state where power for operation cannot be supplied to various devices when the remaining amount of the storage battery 43 becomes lower than this. The storage battery remaining amount monitoring unit 59 corresponds to storage battery remaining amount monitoring means.

  The state detection determination control unit 56 is provided with a power supply switching unit 60 that switches the storage battery 43 used as a backup power source to either one of 43a and 43b based on the monitoring result of the storage battery remaining amount monitoring unit 59. When the remaining storage battery 43 in use becomes low, the power supply switching unit 60 switches the use to another fully charged storage battery 43. In addition, the power source switching unit 60 sends a charging current to the low-remaining storage battery 43 via the DC / DC converter 47 during a period when power supply to the load 58 is not required, and the storage battery 43 used before the switching is supplied to the storage battery 43. Perform charging. The power supply switching unit 60 corresponds to power supply switching means.

  The state detection determination control unit 56 includes a discharge capacity integration unit 61 that integrates the discharge current Ih from full charge when the storage battery 43 in use takes a discharge operation, and the usable capacity of the storage battery 43 from the integrated discharge current value. And a storage battery capacity calculation unit 62 for calculating. The discharge current Ih of the first storage battery 43a is calculated from the detection value of the first storage battery current detection unit 50, and the discharge current Ih of the second storage battery 43b is calculated from the detection value of the second storage battery current detection unit 54. The storage battery capacity calculation unit 62 calculates this discharge current integrated value as a usable capacity of the storage battery 43, that is, a value indicating how much the storage battery 43 can be charged. The discharge capacity integrating unit 61 corresponds to a discharge capacity integrating unit, and the storage battery capacity calculating unit 62 corresponds to a storage battery capacity calculating unit.

Next, operation | movement of the electric power supply system 1 of this example is demonstrated according to FIG.
First, as shown in FIG. 4A, it is assumed that the first storage battery 43a is used as a backup power source and the second storage battery 43b is fully charged. At this time, the first opening / closing switch 49 is turned on, and the second opening / closing switch 53 is turned off. Then, for example, when a backup power source is required due to a power failure in the house, as shown in FIG. 4B, the first storage battery 43a functions as a backup power source, and a discharge current Ih is passed from the first storage battery 43a.

  At this time, the discharge rate detection unit 57 calculates the discharge rate K1 based on the detection value of the first storage battery voltage detection unit 51. Then, the storage battery remaining amount monitoring unit 59 compares the discharge speed K1 with the threshold value Kr, and monitors whether or not the first storage battery 43a is low.

  As shown in FIG. 4 (c), the storage battery remaining amount monitoring unit 59 recognizes that the first storage battery 43a has become low when it confirms that the discharge speed K1 has become equal to or less than the threshold value Kr, and requests power switching. Is output to the power supply switching unit 60. Upon receiving this power supply switching request, the power supply switching unit 60 turns off the first opening / closing switch 49, turns on the second opening / closing switch 53, and supplies the backup power from the first storage battery 43a so far to the second fully charged state. Switch to the storage battery 43b. Thereby, even if the 1st storage battery 43a becomes low, it becomes possible to supply electric power to the load 58 continuously.

  When the first storage battery 43a is discharged, the discharge capacity integration unit 61 integrates the discharge current Ih based on the detection value of the first storage battery current detection unit 50. And the storage battery capacity calculation part 62 calculates the usable capacity of the 1st storage battery 43a based on this discharge current integrated value. Then, the storage battery capacity calculation unit 62 may replace the storage battery 43 with a new one when confirming that the usable capacity is equal to or less than the reference value. In addition, when the speed at which the usable capacity reaches the reference value or less is increased, or when the number of times the available capacity reaches the reference value or less becomes a predetermined number or more, the replacement of the storage battery 43 may be announced.

  Further, as shown in FIG. 4D, when power supply to the load 58 becomes unnecessary, the power supply switching unit 60 turns on the first opening / closing switch 49 and the first storage battery used before switching. 43a is charged. The power supply switching unit 60 receives power to the first storage battery 43a every time when it is not necessary to supply power to the load 58, and recovers the first storage battery 43a to full charge.

  When the second storage battery 43b is used as a backup power source, the discharge rate K2 of the second storage battery 43b is also calculated in the same format as that of the first storage battery 43a. The usable capacity of the second storage battery 43b is calculated in the same manner. When the discharge rate K2 becomes equal to or lower than the threshold value Kr, the use is switched to the first storage battery 43a that has been restored to full charge. In this way, the first storage battery 43 a and the second storage battery 43 b are alternately used as a backup power source for the power supply system 1.

  In this example, the remaining battery level of the storage battery 43 is determined by calculating the discharge speed K when the storage battery 43 takes a discharging operation and checking whether the discharge speed K takes a value equal to or less than the threshold value Kr. To do. Therefore, since the remaining amount of the storage battery 43 is determined based on the parameter of the discharge speed K of the storage battery 43, it becomes possible to detect the remaining battery amount of the storage battery 43 in a highly accurate format. For this reason, when the battery remaining amount of the storage battery 43 is monitored, it is possible to determine the remaining amount of the storage battery 43 based on the battery remaining amount to be truly seen.

  The calculation of the usable capacity of the storage battery 43 is not limited to the calculation from the discharge current Ih of the storage battery 43, and may be calculated from the charging current Ij of the storage battery 43, for example. In this case, as shown in FIG. 2, the state detection determination control unit 56 is provided with a charge capacity integration unit 63 that integrates the charging current Ij when the storage battery 43 is charged. The charging current Ij of the first storage battery 43a is calculated from the detection value of the first storage battery current detection unit 50, and the charging current Ij of the second storage battery 43b is calculated from the detection value of the second storage battery current detection unit 54. The storage battery capacity calculation unit 62 calculates this charging current integrated value as the usable capacity of the storage battery 43. The charge capacity integrating unit 63 corresponds to a charge capacity integrating unit.

  Further, the usable capacity of the storage battery 43 may be calculated from the average of the discharge current integrated value and the charge current integrated value. That is, the storage battery capacity calculation unit 62 adds 2 to the sum of the discharge current integrated value calculated when discharging the storage battery 43 and the charge current integrated value calculated when charging the storage battery 43 when the remaining amount is low. The average value obtained by this is calculated as the usable capacity of the storage battery 43. Therefore, the usable capacity of the storage battery 43 can be obtained as a highly accurate value that is an average of the discharge current integrated value and the charge current integrated value.

According to the configuration of the present embodiment, the following effects can be obtained.
(1) The discharge rate K of the storage battery 43 is calculated, and the remaining battery level of the storage battery 43 is detected by comparing the discharge rate K with the threshold value Kr. For this reason, since it is possible to determine the remaining battery level with a parameter that allows the remaining amount of the storage battery 43 to be accurately viewed as the discharge rate K, the remaining battery level of the storage battery 43 can be viewed with higher accuracy. .

  (2) When the remaining battery capacity of the storage battery 43 becomes low, the use is switched to another storage battery 43, so even if the remaining battery capacity of the storage battery 43 in use decreases, the load continues. 58 can be powered.

  (3) The discharge current Ih from the full charge of the storage battery 43 is integrated, and the usable capacity of the storage battery 43 is calculated from this integrated discharge current value. Therefore, in addition to accurately checking the lower limit remaining capacity of the storage battery 43, the usable capacity of the storage battery 43 can also be grasped.

(4) Since the constant current load 58 is used as a load to which the discharge current Ih is supplied, the remaining amount of the storage battery 43 can be detected with higher accuracy.
(5) The charging current Ij flowing into the storage battery 43 is integrated, and the usable capacity of the storage battery 43 can be calculated from this integrated charging current value. Therefore, the usable capacity of the storage battery 43 can be calculated not only with the discharge current Ih but also with the charging current Ij as a parameter.

  (6) The average value of the discharge current integrated value obtained when the storage battery 43 is discharged and the charge current integrated value obtained when the storage battery 43 is charged can be calculated as the usable capacity of the storage battery 43. Therefore, the usable capacity of the storage battery 43 can be derived more accurately.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIG. Note that this example differs from the first embodiment only in that the remaining amount detection of the storage battery 43 is set to another type. Accordingly, the other basic configuration is the same as that of the first embodiment, and therefore, the same parts are denoted by the same reference numerals, detailed description thereof is omitted, and only different parts are described in detail.

  As shown in FIG. 5, after the backup power source is switched from the first storage battery 43a to the second storage battery 43b, the discharge speed detection unit 57 changes the charge of the second storage battery 43b to the first storage battery 43a that has a small remaining amount. To discharge. And the discharge rate detection part 57 compares the discharge rate K at this time with the threshold value Kr, and monitors the battery remaining amount of the 2nd storage battery 43b. Therefore, in the case of this example, the constant current load at the time of detecting the battery remaining amount of the second storage battery 43b is the other storage battery 43, that is, the first storage battery 43a having a small remaining amount used before switching. .

  As shown in FIG. 5 (a), assuming that the first storage battery 43a is used as a backup power source and the second storage battery 43b is fully charged, first, a constant current load is applied from the first storage battery 43a. A discharge current Ih is supplied to 58. And as shown in FIG.5 (b), when the discharge rate K1 becomes below the threshold value Kr, the backup power supply to be used is switched from the 1st storage battery 43a to the 2nd storage battery 43b. Thereby, even if the 1st storage battery 43a becomes low, it becomes possible to supply electric power to the load 58 continuously.

  At this time, as shown in FIG. 5 (c), when power supply to the load 58 becomes unnecessary, the operation of causing the discharge current Ih to flow from the second storage battery 43b to the load 58 is stopped and constant from the second storage battery 43b. Is discharged to the first storage battery 43a, and the charge of the second storage battery 43b is discharged to the first storage battery 43a. At this time, the discharge rate detector 57 calculates the discharge rate K2 of the second storage battery 43b. The discharge speed detection unit 57 continues to flow the discharge current Ihx until the discharge speed K2 becomes equal to or lower than the threshold value Kr. If power supply to the load 58 is necessary during this time, the operation of flowing the discharge current Ihx is temporarily stopped. A current Ih is supplied to the load 58. And the discharge speed detection part 57 will restart the operation | movement which flows the discharge current Ihx to the 1st storage battery 43a, if the electric power supply to the load 58 becomes unnecessary.

  And the storage battery residual amount monitoring part 59 will notify the power supply switching part 60 that the 2nd storage battery 43b became low, if it confirms that the discharge speed K2 became below the threshold value Kr. By the way, since the 1st storage battery 43a is charged by the discharge current Ihx of the 2nd storage battery 43b, the battery residual amount has recovered | restored. Therefore, the power supply switching part 60 will switch a backup power supply from the 2nd storage battery 43b to the 1st storage battery 43a, if it confirms that the 2nd storage battery 43b became low. Thereby, when the remaining amount of the second storage battery 43b becomes low, the backup power source is switched to the first storage battery 43a, and continuous power supply becomes possible.

  As shown in FIG. 5D, the remaining second storage battery 43b is charged with the charging current Ij during a period when power supply to the load 58 is not required. And whenever discharge rate K1 of the 1st storage battery 43a becomes below threshold value Kr and remaining amount is low, the operation | movement of the flow shown to Fig.5 (a)-(d) is repeated, and the 1st storage battery 43a and 2nd The storage battery 43b is alternately used as a backup power source.

According to the configuration of the present embodiment, in addition to (1) to (6) which are the effects of the first embodiment, the following effects can be obtained.
(7) In the case of this example, the constant current load required to discharge the storage battery 43 (second storage battery 43b) under a constant current was substituted with another storage battery 43 (first storage battery 43a). By the way, the storage battery 43 is a load that actually consumes energy during operation. If the discharge speed K can be detected using such a load, the remaining amount of battery can be detected with low energy loss. can do.

Note that the embodiment is not limited to the configuration described so far, and may be modified as follows.
-In 1st and 2nd embodiment, the threshold value Kr is good also as a different value by the 1st storage battery 43a and the 2nd storage battery 43b.

In the first and second embodiments, the threshold value Kr is not limited to a fixed value, and may be a variable value.
In the first and second embodiments, the self-supporting power generation battery is not limited to the solar battery 3 and may be a fuel cell, for example.

-In 1st and 2nd embodiment, the storage battery 43 can employ | adopt various electrical storage members, such as a secondary battery and a capacitor | condenser.
In the first and second embodiments, for example, a constant current circuit may be incorporated in the storage battery unit 16 so that the discharging operation is performed under a constant current.

-In 1st and 2nd embodiment, when the storage battery 43 becomes low, for example, a power supply may be switched to a fuel cell.
In the first and second embodiments, the usable capacity of the storage battery 43 is calculated by looking at the time required for the storage battery 43 to become low or the time required for the storage battery 43 to be fully charged. May be.

In the first and second embodiments, the number of storage batteries 43 is not limited to two, and may be three or more.
-In 1st and 2nd embodiment, the system | strain 2 may supply not only the commercial alternating current power supply which supplies an alternating voltage but a direct current voltage.

-In 1st and 2nd embodiment, the electric power supply system 1 is not restricted to being used for a house, For example, you may apply to other buildings, such as a factory.
-In 1st and 2nd embodiment, if the function part which can comprise the characteristic structure requirements of this invention is a structural member of the electric power supply system 1, it may be provided anywhere.

The various technical ideas described in the first embodiment and the various technical ideas described in the second embodiment may be appropriately combined.
Next, technical ideas that can be grasped from the above-described embodiment and other examples will be described below together with their effects.

  (A) In any one of Claims 1-7, the power line communication control part which supplies electric power and data to the said load via power line communication, and controls this load was provided. According to this configuration, the load can be controlled by power line communication, so that power and data can be supplied to the load with a small number of wires.

  DESCRIPTION OF SYMBOLS 1 ... Electric power supply system, 2 ... System | strain, 3 ... Solar cell as a self-supporting power generation battery, 5 ... DC apparatus which comprises load, 6 ... AC apparatus which comprises load, 43 (43a, 43b) ... Storage battery (other storage battery) ), 57... Discharge rate detection unit as discharge rate detection means, 58... Constant current load constituting the load, 59... Storage battery remaining amount monitoring unit as storage battery remaining amount monitoring means, and 60. 61 ... Discharge capacity integration unit as discharge capacity integration means, 62 ... Storage battery capacity calculation section as storage battery capacity calculation means, 63 ... Charge capacity integration section as charge capacity integration means, K (K1, K2) ... Discharge rate, Kr ... threshold, Ih (Ihx) ... discharge current, Ij ... charge current.

Claims (7)

Storage battery remaining amount monitoring of a power supply system in which a voltage obtained from a system or a stand-alone power generation battery is converted into a voltage while being branched and supplied to each load, and a storage battery is mounted as a backup power source for the system or the stand-alone power generation battery In the device
A discharge rate detecting means for detecting a discharge rate under a constant current of the storage battery;
A storage battery remaining amount monitoring device for a power supply system, comprising: a storage battery remaining amount monitoring means for monitoring the remaining amount of the storage battery by comparing the discharge rate with a threshold value.   The storage battery remaining amount monitoring device for a power supply system according to claim 1, further comprising power switching means for switching a power source of the load to another storage battery when the discharge speed becomes equal to or less than the threshold value. Discharge capacity integrating means for integrating the discharge current from full charge of the storage battery;
The storage battery remaining amount monitoring device for a power supply system according to claim 1 or 2, further comprising storage battery capacity calculation means for calculating an available capacity of the storage battery from an integrated value of the discharge capacity integration means.   The load is a constant current load that is controlled by itself so that a discharge current is constant, and the discharge rate is a discharge rate generated when electric power is discharged to the constant current load. The storage battery residual amount monitoring apparatus of the electric power supply system as described in any one of claim | item 1 -3.   The constant current load that changes the voltage of the storage battery under a constant current during discharge is another storage battery that is not used as a power source for the load, and the discharge speed is determined when discharging to the other battery. The storage battery residual amount monitoring apparatus of the power supply system according to any one of claims 1 to 4, wherein a discharge rate of Charging capacity integrating means for integrating charging current when charging the storage battery,
The storage battery of the power supply system according to any one of claims 1 to 5, further comprising storage battery capacity calculation means for calculating a usable capacity of the storage battery from an integrated value of the charge capacity integration means. Remaining amount monitoring device. Discharge capacity integrating means for integrating the discharge current from full charge of the storage battery;
Charging capacity integrating means for integrating charging current when charging the storage battery;
The storage battery capacity calculating means for calculating the usable capacity of the storage battery from the average value of the integrated value of the discharge capacity integrating means and the integrated value of the charging capacity integrating means. 6. A storage battery residual amount monitoring device for a power supply system according to claim 1.

Images