JP2014220874A - Power supply system, control device for power supply system, control method for power supply system, and power supply program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To appropriately control power consumption of a load in an emergency such as the case that power supply from a main power source stops, to continue operation of the load until the emergency with respect to the main power source is solved.SOLUTION: In the case that a state where power supply from a main power stops continues for a long time, a power supply system transmits a stop signal 34 to a load through a power supply line when power residual capacity of a secondary battery 10 becomes equal to or lower than a predetermined threshold 1; and the load is made to be in a sleep state or stop state to reduce power consumption of the load as much as possible when receiving the signal. On the other hand, the power supply system charges the secondary battery 10 with power from a renewal power supply unit 15 such as a solar cell 11, and shifts to a state where the power residual capacity of the secondary battery can make the load stably operate when the power residual capacity exceeds another predetermined threshold 2.

Description

  The present invention provides a backup in a state where power supply from the main power supply is stopped (for example, a power failure) separately from a main power supply such as a commercial power supply when power is supplied to a device arranged in an office, a store, a house, etc. The present invention relates to a power supply system suitable for power supply, a control device for the power supply system, a control method for the power supply system, and a power supply program.

Conventionally, a power generation apparatus that generates power using DC power generated by converting AC power of a commercial power source supplied from a power system by an AC / DC converter, and natural energy such as a solar battery, wind power generation, and tidal power generation There is known a direct current distribution system that distributes power to a load in cooperation with direct current power from a power source. Such a DC power distribution system generally includes a secondary battery as an emergency power source for supplying DC power to a DC load in an emergency such as when the power system is stopped. In addition, the secondary battery is charged with DC power supplied from an AC / DC converter or a solar battery, wind power generation, tidal power generation, etc. at all times, and the charging power of the secondary battery is discharged during a power outage and loaded. It is comprised so that it may supply.
FIGS. 9A, 9B, and 9C are graphs showing the operation of a conventional DC power distribution system. After the power failure occurs, power from the secondary battery is supplied to the load, and the load is backed up. When the power failure continues, the battery power remaining capacity 120 shown in FIG. 9A decreases, and the battery power remaining capacity 120 disappears, the power supply from the battery is lost (point A). In that case, the power consumption can be supplied to the load using the solar cell generated power 121.
However, the power generation apparatus that generates power using natural energy typified by solar cells has unstable power generation. For example, solar cells cannot obtain the amount of power generation required to drive equipment in the rain or at night. As shown in FIG. 9B, the power consumption of the load (indicated by the dotted line B) cannot be stably supplied. Only when the solar cell generated power 121 exceeds the power consumption of the load, the load is stably backed up. As shown in FIG. 9C, the load is stably backed up during the period (region C) in which the power from the secondary battery and the power from the solar battery are supplied, but the solar cell generated power 121 is Because the power is unstable, the power supplied is lower than the power required (area D), and unstable power is supplied to the load. Therefore, the load stops without being controlled. The operation starts when the solar cell generated power exceeds the power consumption of the load. However, since the load is not controlled, there is a problem that the operation becomes unstable and continuous processing cannot be performed. In general, since the secondary battery cannot be charged during discharging, as shown in FIG. 9A, the battery cannot be charged during the period when power is supplied from the secondary battery to the load after the power failure occurs. Disappears.

For example, in the power supply system described in Patent Document 1, when power is supplied to a load only by a power source such as a secondary battery provided separately from the main power source in the event of a power failure, the number of devices that supply power from the secondary battery is limited. Thus, there is disclosed a power supply system that makes it possible to specify a device easily by allowing a necessary device to operate reliably and to directly specify a device that needs to be fed from a secondary battery.
That is, according to the technique disclosed in Patent Document 1, a device selection unit that selects a device to be fed from the power supply unit according to the priority stored in the priority storage unit is provided, and the device selection unit is not selected. In response to this, by instructing the operation to be stopped by the communication means, only the selected device is supplied with power from the secondary battery. As a result, it is possible to limit the number of devices to be fed from the secondary battery at the time of a power failure of the main power source, and it is possible to reliably operate necessary devices even with a limited power capacity of the secondary battery.

In the technique disclosed in Patent Document 1, it is described that only a selected device is supplied with power from a secondary battery, so that necessary devices can be reliably operated even with a limited power capacity of the secondary battery. Has been. However, when a power failure lasts for a long time, the remaining power of the secondary battery is reduced, and eventually the remaining power of the secondary battery is insufficient, so that power cannot be supplied to the load. Therefore, there is a problem that the load cannot be operated until the power failure of the main power source is resolved and the load can be supplied with power from the main power source.
In addition, DC power from power generation devices that use natural energy, such as solar cells, wind power generation, and tidal power generation, is often small in power capacity that can be supplied compared to the main power supply, and is continuously stable. It is difficult to supply power to For example, a solar cell cannot obtain the amount of power generation required for driving the device in rainy weather or at night. In addition, the amount of power generated by wind power generation varies depending on the strength of the wind, and the amount of power generated by tidal power generation varies depending on the state of the sea. As described above, since the power generated by natural energy cannot be stably supplied to the load device, the load device cannot be operated until the load can be supplied by the power source from the main power source. Therefore, it is anxious that the load device can operate until the power can be supplied from the main power source to the load.

  The present invention has been made in view of the above, and its purpose is to appropriately control the power consumption of the load in an emergency such as when power supply from the main power supply is stopped, thereby eliminating the emergency of the main power supply. Another object of the present invention is to provide a power supply system, a system control device, and a control program that can continue the operation of the load until the load is reached.

  In order to solve the above problem, the invention according to claim 1 is a main power supply and a secondary battery that supplies power to at least one load device instead of the main power supply when power supply from the main power supply is stopped. A regenerative power supply means for supplying power generated by a power generator using natural energy to the secondary battery, and a secondary battery for detecting the remaining power of the secondary battery A remaining capacity detecting means; and a control means for controlling the operating state of the load device, wherein the control means detects when the power supply from the main power supply is stopped by the secondary battery remaining capacity detecting means. When the remaining power of the secondary battery becomes equal to or less than a first threshold, the load device is controlled to enter a sleep state or a stop state, and the secondary power is supplied by the power supplied from the regenerative power supply means. Remaining battery When the remaining power of the secondary battery detected by the amount detection means exceeds a second threshold value that is higher than the first threshold value, the load device is activated and controlled to be in an operating state. Features.

  According to the present invention, the power generated by the power generation device using natural energy is supplied to the secondary battery, and the operation state of the load device is controlled based on the remaining power of the secondary battery. The power consumption of the load can be appropriately controlled in an emergency such as when the power supply is stopped, and the operation of the load can be continued until the emergency of the main power supply is eliminated.

1 is a block diagram illustrating an overall configuration of a power supply system according to a first embodiment of the present invention. FIG. 2 is a graph showing the time change of the remaining battery power. (A) is a graph which shows the change of battery power remaining capacity, (b) is a graph which shows a solar cell electric power generation change, (c) is a graph which shows the change of the power consumption of load. It is a block diagram which shows the whole structure of the electric power supply system concerning 2nd Embodiment of this invention. It is a block diagram which shows the whole structure of the electric power supply system concerning 3rd Embodiment of this invention. It is a block diagram which shows the whole structure of the electric power supply system concerning 4th Embodiment of this invention. It is a block diagram which shows the whole structure of the electric power supply system concerning 5th Embodiment of this invention. It is a block diagram which shows the whole structure of the electric power supply system concerning 6th Embodiment of this invention. (A), (b), (c) is a graph which shows operation | movement of the conventional DC distribution system.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
FIG. 1 is a block diagram showing the overall configuration of a power supply system 1A according to the first embodiment of the present invention. As shown in FIG. 1, a DC power supply unit 2 that outputs DC power and a DC device (loads 3 to 5) (load device) as loads driven by the DC power are provided. DC power is supplied to the loads 3 to 5 through the power supply line 6 connected to the output end of the load 3.
The power supply line 6 is a DC power supply path and is also used as a communication path, and is connected to the power supply line 6 by superimposing a communication signal for transmitting data on a DC voltage using a high-frequency carrier wave. It enables the power line communication function between devices. This technique is similar to a power line carrier technique (PLC) in which a communication signal is superimposed on an AC voltage in a power line that supplies AC power.
The power line communication unit 7 (7a to 7e) includes, for example, a power line communication modulation / demodulation unit, an A / D conversion unit, a D / A conversion unit, and a coupler circuit (not shown). The communication data is modulated into a power line communication signal by the power line communication modem. As the modulation method, 256QAM, 64QAM, 16QAM, QPSK, BPSK, or the like is adopted, which is determined by a necessary transmission rate and a transmission error rate by power line communication. The power line communication modulation / demodulation unit may include an up / down conversion function. The output of the power line communication modulation / demodulation unit becomes an analog signal in the D / A conversion unit, and the communication signal is applied to the power line through the coupler circuit.
For example, in the case of an office, the power supply line 6 is connected to an information equipment system including information system DC equipment such as a server, a copier, a multifunction printer, a personal computer, a wireless access point, a router, and an IP telephone.

The DC power supply unit 2 basically generates DC power by power conversion of an AC power supply 8 supplied like a commercial power supply. In the configuration shown in FIG. 1, an AC power supply 8 that is a commercial power supply is input to an AC / DC converter 9 including a switching power supply. The DC power output from the AC / DC converter 9 is supplied to the loads 3 to 5 through the power supply line 6.
In the power supply system 1 of the present embodiment, a secondary battery 10 is provided in preparation for a period in which power is not supplied from the AC power supply 8 (for example, a power failure period of the commercial power supply AC). Moreover, the solar cell 11 which produces | generates direct-current power is provided as a power generator which produces electric power using natural energy. In contrast to the DC power supply unit 2 including the AC / DC converter 9 that generates DC power from the AC power supply 8, the solar battery 11 and the secondary battery 10 serve as backup power supplies during a period in which the DC power supply unit 2 is not output. In FIG. 1, the solar battery 11 is connected to a DC / DC converter 12 that controls the output voltage, and the secondary battery 10 is connected to a charging circuit 13 and a discharging circuit 14 that control discharging and charging.

The secondary battery 10 is charged in a timely manner by a regenerative power supply unit 15 such as the DC power supply unit 2 or the solar battery 11. The secondary battery 10 is discharged not only in a period in which power is not supplied from the AC power supply 8 but also in a timely manner as necessary. The control unit 16 performs charge / discharge of the secondary battery 10 and cooperation between the DC power supply unit 2 and the regenerative power supply unit 15. That is, the control unit 16 functions as a DC power control unit that controls the distribution of power from the main power source and the regenerative power supply unit 15 and the secondary battery 10 to the DC device constituting the DC power supply unit 2.
Since the drive voltage of the DC device is selected from a plurality of types of voltages according to the device, a plurality of DC / DC converters are provided and obtained from the DC power supply unit 2, the regenerative power supply unit 15 and the secondary battery 10. The generated DC voltage may be converted into a necessary voltage.

The DC power supply unit 2, the regenerative power supply unit 15, the secondary battery 10, the control unit 16, and the loads 3 to 5 described above are provided with a communication function. For this reason, it is possible to perform a cooperative operation to deal with the state of the DC power supply unit 2, the regenerative power supply unit 15 including the solar battery 11, the secondary battery 10, and the load including the DC device. The communication signal used for the power line communication units (7a to 7e) is transmitted in a form superimposed on the DC voltage, similarly to the communication signal used for the DC device.
That is, in FIG. 1, the DC power supply unit 2 generates desired DC power by converting power from the commercial power supply 8 using the AC / DC converter 9. The regenerative power supply unit 15 generates desired DC power by converting the power generated from the solar battery 11 in the present embodiment, which generates power using natural energy, by the DC / DC converter 12. .

The secondary battery 10 is connected to a charging circuit 13 and a discharging circuit 14 to charge and discharge DC power. The secondary battery 10 is connected to a remaining power detection unit 18, and the remaining power of the secondary battery is monitored by the threshold 1 comparison unit 19 and the threshold 2 comparison unit 20. Control of the secondary battery 10, the charging circuit 13, and the discharging circuit 14 is performed by the battery control unit 21.
The loads 3 to 5 include a function unit 17 that executes the operation of the load and a sleep / stop load control unit 22 that changes the operation mode to the sleep state or the stop state.
The control unit 16 controls the distribution of power from the DC power supply unit 2, the regenerative power supply unit 15 and the secondary battery 10 to the DC device, and also receives a power failure (commercial power supply 8) using a signal from the power failure detection unit 23. The power supply from 8 is stopped) and the power failure backup operation is controlled to function as the DC power supply unit 2.
The DC power supply unit 2, the regenerative power supply unit 15, the secondary battery 10, the control unit 16, and the loads 3 to 5 described above are provided with a communication function. Then, a power line for performing a cooperative operation to deal with the state of a DC power supply unit 2 including a commercial power source (main power source) 8, a regenerative power supply unit 15 including a solar battery 11, a secondary battery 10, a load including a DC device, etc. It has communication parts 7a-7e. In the power line communication units 7a to 7e, the communication signal is transmitted in a form superimposed on the DC voltage, similarly to the communication signal used for the DC device.

DC power is supplied from the DC power supply unit 2 to the plurality of loads 3 to 5 connected to the power supply line 6 during a period in which the commercial power supply 8 that is a commercial power supply is supplied. The battery power remaining capacity of the secondary battery 10 is charged until it reaches a predetermined remaining capacity during the period in which the AC power AC that is the commercial power supply 8 is supplied. Generally, in the case of a backup application for power failure, the secondary battery is charged until it is fully charged.
When the power failure of the commercial power supply 8 occurs, the DC power from the DC power supply unit 2 is not supplied. The control unit 16 detects a power failure of the commercial power supply 8 using a signal from the power failure detection unit 23. It is conceivable that the power failure detection unit 23 detects a power failure from the state of the power supply line 6 or detects a power failure from the state of the commercial power supply 8 as described by a broken line 24.
The control unit 16 instructs the battery control unit of the secondary battery to discharge DC power from the secondary battery 10 for backup during the power failure period via the power supply line by the power line communication unit. The battery control unit 21 controls the discharge circuit 14 of the secondary battery 10 in accordance with an instruction from the control unit 16 to discharge desired DC power to the power supply line 6, so that DC power is supplied to the plurality of loads 3 to 5. Supplied. During the period in which power is supplied from the secondary battery 10, DC power supplied to the loads 3 to 5 (strictly speaking, including power loss such as a discharge circuit) is supplied from the secondary battery 10. The remaining battery power capacity of the secondary battery 10 is reduced.

  When the remaining battery power becomes equal to or less than a predetermined threshold 1, it is detected from the output of the remaining power detection unit 18 of the secondary battery 10 that the threshold 1 comparison unit 19 is equal to or less than the predetermined threshold 1. Then, the battery control unit 21 is notified. The battery control unit 21 notifies the control unit 16 that the remaining battery power capacity has become equal to or less than a predetermined threshold 1 via the power supply line 6 by the power line communication unit 7C. The control unit 16 transmits a stop signal that instructs the plurality of loads 3 to 5 to enter a sleep state or a stop state via the power supply line 6. The loads 3 to 5 receive a stop signal instructing to enter the sleep state or the stop state, and control the load function unit 17 to change the operation mode to the sleep state or the stop state.

Since the loads 3 to 5 are in the sleep state or the stop state, the power consumption is extremely reduced. On the other hand, the DC power from the regenerative power supply unit 15 including the solar battery 11 charges the secondary battery 10 with DC power excluding very little DC power supplied to the load in the stopped state due to the sleep state described above. . The control unit 16 instructs the battery control unit 21 of the secondary battery 10 to activate the charging circuit 13 and charge the secondary battery 10 via the power supply line 6 by the power line communication unit 7C. In order to stably operate the loads 3 to 5, the discharge circuit 14 discharges a very small amount of DC power supplied to the load in the stopped state due to the sleep state described above. In general, the DC power used by the load in the sleep state or in the stopped state is smaller than the DC power from the regenerative power supply unit 15 including the solar battery 11. Therefore, the difference may be instructed as charging power, and the remaining DC power may be used by the load to stop the discharge circuit 14 and reduce the loss.
Since the secondary battery 10 is charged with DC power from the regenerative power supply unit 15 including the solar battery 11, the battery power remaining capacity increases. When the remaining battery power becomes equal to or greater than a predetermined threshold 2 (threshold 2> threshold 1), the control unit 16 transmits an activation signal instructing a plurality of loads to enter an operating state via the power supply line 6. To do. The loads 3 to 5 receive the activation signal instructing to enter the operation state, and control the function unit 17 of the loads 3 to 5 to change to the normal operation mode. As a result, the commercial power supply 8 is supplied with DC power from the secondary battery 10 to the plurality of loads 3 to 5 even when the power failure continues.

  Further, if the power failure is continuing, the relationship between the threshold value 1 and the threshold value 2 is repeated, so that the load can be stably operated for a certain time while the power failure is occurring. Further, when the power failure of the commercial power supply 8 is resolved, DC power is supplied from the DC power supply unit 2 to the plurality of loads 3 to 5 connected to the power supply line 6 as usual. Although not shown, the secondary battery 10 is charged from the DC power supply unit 2 or the regenerative power supply unit 15 and charged until a predetermined remaining battery power capacity is provided in preparation for the next power failure backup.

Next, the operation of the present embodiment will be described with reference to FIG.
FIG. 2 is a graph showing the time change of the remaining battery power. The vertical axis of the graph shown in FIG. 2 indicates the remaining battery power 30 of the secondary battery 10, and the horizontal axis indicates the passage of time 31. During the period (A) in which the AC power supply 8 that is a commercial power supply is supplied, DC power is supplied from the DC power supply unit 2 to the plurality of loads 3 to 5 connected to the power supply line 6. The battery power remaining capacity of the secondary battery 10 is charged until a predetermined remaining capacity is reached before the period (A). Generally, in the case of a backup application for power failure, the secondary battery 10 is charged until full charge.
A power failure 32 of the commercial power source AC occurs at the start of the period (B). When the power failure 32 occurs, the DC power from the DC power supply unit 2 is not supplied. Therefore, DC power is supplied from the secondary battery 10 to the plurality of loads 3 to 5 as a backup during the power failure period. During the period when power is supplied from the secondary battery 10, the secondary battery 10 supplies the DC power supplied to the load (strictly speaking, including power loss such as a discharge circuit) from the secondary battery 10. The battery power remaining capacity of the battery 10 is reduced. In the period (B), the battery power remaining capacity 30 is decreasing as shown by the straight line 33.
When the remaining battery power 30 falls below a predetermined threshold 1, the control unit 16 transmits a stop signal that instructs the plurality of loads 3 to 5 to enter a sleep state or a stop state via the power supply line 6. To do. The loads 3 to 5 receive a stop signal instructing to enter the sleep state or the stop state, and control the load function unit 17 to change the operation mode to the sleep state or the stop state. The start point of the period (C) is a time point when the remaining battery power becomes a predetermined threshold value 1 or less, and the control unit instructs a plurality of loads to enter a sleep state or a stop state via power line communication. This is the time when the stop signal 34 to be transmitted is transmitted.

In the period (C), the loads 3 to 5 are in the sleep state or the stop state, so that the power consumption is extremely reduced. On the other hand, the DC power from the regenerative power supply unit 15 including the solar battery 11 is obtained by subtracting the DC power obtained by subtracting very little DC power supplied to the loads 3 to 5 in the sleep state from the sleep state described above to the secondary battery 10. Charge. Since the secondary battery 10 is charged during the period (C), the remaining battery power 30 is increased.
At the end of the period (C), the battery power remaining capacity 30 is a time when the predetermined threshold value 2 or more is reached. When the remaining battery power reaches a predetermined threshold value 2 or more, the control unit 16 transmits an activation signal 35 that instructs the plurality of loads 3 to 5 to enter an operating state via the power supply line 6. The loads 3 to 5 receive the activation signal 35 instructing to enter the operation state, and control the function unit 17 of the loads 3 to 5 to change to the normal operation mode.

In the period (D), the commercial power supply 8 is continuing a power failure, and DC power is supplied to the plurality of loads 3 to 5 from the secondary battery 10 as in the period (B). During the period in which power is supplied from the secondary battery 10, DC power supplied to the loads 3 to 5 (strictly speaking, including power loss such as a discharge circuit) is supplied from the secondary battery 10. The battery power remaining capacity 30 of the secondary battery 10 is reduced.
If the power outage continues after the period (D), the remaining battery power 30 changes between the threshold value 1 and the threshold value 2 so that the loads 3 to 5 are stable for a certain period of time while the power outage is occurring. It becomes possible to operate. Further, when the power failure of the commercial power supply 8 is resolved, DC power is supplied from the DC power supply unit 2 to the plurality of loads 3 to 5 connected to the power supply line 6 as usual. Although not shown, the secondary battery 10 is charged from the DC power supply unit 2 or the regenerative power supply unit 15 and charged until a predetermined remaining battery power capacity is provided in preparation for the next power failure backup.

3A is a graph showing the change in the remaining battery power capacity, FIG. 3B is a graph showing the change in the solar battery power generation, and FIG. 3C is a graph showing the change in the power consumption of the load. is there. After the power failure occurs, power from the secondary battery 10 is supplied to the loads 3 to 5, and the loads 3 to 5 are backed up. When the power failure continues and the battery power remaining capacity 30 shown in FIG. 3A decreases and the battery power remaining capacity 30 falls below a predetermined threshold 1 (point A), the control unit 16 passes the power supply line 6. A stop signal 34 is transmitted to instruct the plurality of loads 3 to 5 to enter the sleep state or the stop state.
The loads 3 to 5 receive the stop signal 34 instructing to enter the sleep state or the stop state, and control the function unit 17 of the loads 3 to 5 to change the operation mode to the sleep state or the stop state. When the remaining battery power 30 becomes the threshold value 1 or less (point A), the loads 3 to 5 are put into a sleep state by the stop signal 34 and only very little sleep power is stably supplied from the solar battery 11 of the regenerative power supply unit 15. Supplied. When the remaining battery power 30 becomes the threshold value 2 or more (point B), the loads 3 to 5 are activated by the activation signal 35, and stable power is supplied from the secondary battery 10. Since the operations of the loads 3 to 5 are controlled, the controlled loads 3 to 5 can maintain the state before the stop, and continuous processing is possible.

In addition, as shown in FIG. 3B, in this configuration, even when the power from the regenerative power supply unit 12 is unstable, the load during the period in which power is directly supplied by the solar cell 11 is set to the sleep state by the stop signal 34. It has become. For this reason, it is sufficient that only a very small amount of power for sleep can be stably supplied, and a power generation apparatus that generates power using natural energy represented by the solar cell 11 is also possible. If the power failure is continuing, the load can be stably operated for a certain period of time while the power failure occurs by changing between the threshold value 1 and the threshold value 2.
The vertical axis of the graph shown in FIG. 3C indicates the power consumption of the loads 3 to 5, and the horizontal axis indicates the passage of time. A power failure of the commercial power supply AC occurs at the start of the period (A). When a power failure occurs, DC power from the DC power supply unit 2 is not supplied. Therefore, DC power is supplied from the secondary battery 10 to the plurality of loads 3 to 5 as a backup during the power failure period. During the period when power is supplied from the secondary battery 10, the secondary battery 10 supplies the DC power supplied to the load (strictly speaking, including power loss such as a discharge circuit) from the secondary battery 10. The battery power remaining capacity of the battery 10 is reduced. In the period (A), the battery power remaining capacity 30 is decreasing as shown by a straight line 36.

When the remaining battery power 30 becomes a predetermined threshold value 1 or less, the control unit 16 sends a stop signal 34 that instructs the plurality of loads 3 to 5 to enter the sleep state or the stop state via the power supply line 6. Send. The loads 3 to 5 receive the stop signal 34 instructing to enter the sleep state or the stop state, and control the load function unit 17 to change the operation mode to the sleep state or the stop state. The start point of the period (B) is a time point when the remaining battery power 30 becomes equal to or less than a predetermined threshold value 1, and the control unit 16 puts a plurality of loads 3 to 5 in a sleep state or the like via the power supply line 6. This is the time when a stop signal 34 is sent to instruct the stop state.
In the period (B), since the loads 3 to 5 are in the sleep state or the stop state, the power consumption is extremely reduced. On the other hand, the DC power from the regenerative power supply unit 15 including the solar battery 11 is obtained by subtracting the DC power obtained by subtracting very little DC power supplied to the loads 3 to 5 in the sleep state from the sleep state described above to the secondary battery 10. Charge. Since the secondary battery 10 is charged during the period (B), the remaining battery power 30 is increasing.
At the end of the period (B), the battery power remaining capacity 30 is a time point (point B) at which a predetermined threshold value 2 or more is reached. When the remaining battery power 30 reaches a predetermined threshold value 2 or more, the control unit 16 transmits an activation signal 35 for instructing the plurality of loads 3 to 5 to enter an operating state via the power supply line 6. The loads 3 to 5 receive the activation signal 35 instructing to enter the operation state, and control the function unit 17 of the loads 3 to 5 to change to the normal operation mode.

In the period (C), the commercial power supply 8 is continuing a power failure, and DC power is supplied from the secondary battery 10 to the plurality of loads 3 to 5 as in the period (A). During the period in which power is supplied from the secondary battery 10, DC power supplied to the loads 3 to 5 (strictly speaking, including power loss such as a discharge circuit) is supplied from the secondary battery 10. The battery power remaining capacity 30 of the secondary battery 10 is reduced.
If the power failure continues after the period (C), the remaining battery power 30 changes between the threshold value 1 and the threshold value 2 so that the loads 3 to 5 are stable for a certain period of time while the power failure is occurring. It becomes possible to operate. Further, when the power failure of the commercial power supply 8 is resolved, DC power is supplied from the DC power supply unit 2 to the plurality of loads 3 to 5 connected to the power supply line 6 as usual. Although not shown, the secondary battery 10 is charged from the DC power supply unit 2 or the regenerative power supply unit 15 and charged until a predetermined remaining battery power capacity is provided in preparation for the next power failure backup.

In this way, the power generated by the solar battery (power generation device) 11 using natural energy is supplied to the secondary battery 10, the remaining power of the secondary battery 10 is detected, and the secondary battery 10 is charged and discharged. Control the operating state of the load. When the power supply from the commercial power source (main power source) 8 is stopped, the control unit 16 sets the load in the sleep state or when the remaining power of the secondary battery 10 becomes the threshold value 1 (first threshold value) or less. Control to stop. On the other hand, when the remaining power of the secondary battery 10 exceeds the threshold 2 (second threshold) higher than the threshold 1 due to the power supplied from the solar battery (power generation device) 11, the control unit 16 loads the load. Control to start and become operational. Thereby, the power consumption of the load can be appropriately controlled in an emergency such as when power supply from the commercial power supply 8 is stopped, and the operation of the load can be continued until the emergency of the commercial power supply 8 is resolved.
Moreover, the power supply line 6 which supplies the electric power from the reproduction | regeneration electric power supply part 15 and the secondary battery 10 to a load is provided. Then, when the remaining power of the secondary battery 10 becomes equal to or less than the threshold value 1, the control unit 16 transmits a stop signal to the load via the power supply line 6 and puts the load into a sleep state or a stop state. To control. On the other hand, when the secondary battery 10 is charged by the power supplied from the regenerative power supply unit 15 and the remaining power of the secondary battery 10 exceeds the threshold value 2, the control unit 16 passes the power supply line 6. An activation signal is transmitted to the load to control the load to be in an operating state. Thereby, the power consumption of the load can be appropriately controlled in an emergency such as when power supply from the commercial power supply 8 is stopped, and the operation of the load can be continued until the emergency of the commercial power supply 8 is resolved.

Second Embodiment
FIG. 4 is a block diagram showing an overall configuration of a power supply system 1B according to the second embodiment of the present invention. The same components as those in FIG. In the embodiment of FIG. 4, a load power monitoring unit 40 that monitors the power consumption of a plurality of loads connected to the power supply line 6 is provided. In association with the detected load power, the threshold value 1 changing unit 41 changes the value of the threshold value 1, and the threshold value 2 changing unit 42 changes the value of the threshold value 2.
For example, when the power consumption of the load is greater than a predetermined value, the threshold value 2 is set to be large in order to make the load operation time due to restart after a power failure a desired time. For example, to ensure the operating time after restart,
Threshold value 2 = (desired operating time × monitored load power consumption) + threshold value 1
Thus, the operation time can be set according to the power consumption of the load.
When changing the threshold value 2, the control unit 16 instructs the battery control unit 21 via the power supply line 6 by the power line communication unit 7 </ b> C so that the threshold value 2 changing unit 42 is the threshold value 2 comparison unit 20. The threshold value 2 is changed.

For example, when the DC power used by the load in the sleep state or the stopped state at the time of a power failure (and also including the power used by the control unit 16) is smaller than a predetermined value, the remaining battery power becomes 0 at the time of the power failure. It is possible to reduce the target threshold 1 for avoiding the loss of power supply to the power supply line 6. By reducing the threshold value 1, the time from the occurrence of a power failure to the transmission of a stop signal to the load becomes longer, and the operating time of the load becomes longer. The threshold value 1 is changed by the control unit 16 instructing the battery control unit 21 via the power supply line 6 by the power line communication unit 7 d, so that the threshold value 1 changing unit 41 sets the threshold value 2 of the threshold value 1 comparison unit 19. change.
As described above, the load power monitoring unit 40 that monitors the power consumption of the load is provided, and the control unit 16 changes the threshold value 1 or the threshold value 2 in association with the load monitored by the load power monitoring unit 40. The operation time can be set corresponding to

<Third Embodiment>
FIG. 5 is a block diagram showing the overall configuration of a power supply system 1C according to the third embodiment of the present invention. The same components as those in FIG. In the embodiment of FIG. 5, a generated power monitoring unit 43 that monitors the generated power of the regenerative power supply unit 15 is provided. In association with the detected generated power, the threshold value 1 changing unit 41 changes the value of the threshold value 1, and the threshold value 2 changing unit 42 changes the value of the threshold value 2.
For example, when the generated power of the regenerative power supply unit 15 is larger than a predetermined value, the charging power of the secondary battery can be increased in the same charging time. Therefore, since the load operation time due to restart after a power failure can be made longer than a predetermined time, the threshold value 2 is greatly changed. When changing the threshold value 2, the control unit 16 instructs the battery control unit 21 via the power supply line 6 by the power line communication unit 7 d, so that the threshold value 2 changing unit 42 is changed to the threshold value 2 comparison unit 20. The threshold value 2 is changed.
In this way, the power generation monitoring unit 43 that monitors the power generation of the regenerative power supply unit 15 is provided, and the control unit 16 changes the threshold 1 and the threshold 2 in association with the power generation monitored by the power generation monitoring unit 43. Thus, the charging power of the secondary battery can be increased in the same charging time.

<Fourth embodiment>
FIG. 6 is a block diagram showing an overall configuration of a power supply system 1D according to the fourth embodiment of the present invention. The same components as those in FIG. In the embodiment of FIG. 6, a remaining power capacity change rate monitoring unit 44 that monitors temporal changes in the remaining power capacity of the secondary battery when power is supplied from the secondary battery to the load at the time of a power failure is provided. In association with the detected remaining power capacity change rate, the threshold value 1 changing unit 41 changes the value of the threshold value 1, and the threshold value 2 changing unit 42 changes the value of the threshold value 2.
For example, when the remaining power capacity change rate is larger than a predetermined value, it indicates that the power consumption of the load at the time of the power failure is larger than a predetermined DC power, and the load operation time due to restart after the power failure is a desired time. In order to achieve this, the threshold value 2 is set to a large value. When changing the threshold value 2, the control unit 16 instructs the battery control unit 21 via the power supply line 6 by the power line communication unit 7 d, so that the threshold value 2 changing unit 42 is changed to the threshold value 2 comparison unit 20. The threshold value 2 is changed.
As described above, when the power is supplied from the secondary battery 10 to the load, the power remaining capacity change rate monitoring unit 44 that monitors the time change of the remaining power of the secondary battery 10 is provided. Then, the threshold 1 and the threshold 2 are changed in association with the remaining power change rate monitored by the remaining power change rate monitoring unit 44. Thereby, according to the time change of the electric power remaining capacity of the secondary battery 10, the load operation time by the restart of the load after a power failure can be made into desired time.

<Fifth Embodiment>
FIG. 7 is a block diagram showing an overall configuration of a power supply system 1E according to the fifth embodiment of the present invention. The same components as those in FIG. In the embodiment of FIG. 7, a clock unit 45 that measures the current time is provided. In association with the time measured, the threshold value 1 changing unit 41 changes the threshold value 1 and the threshold value 2 changing unit 42 changes the threshold value 2. For example, in an office or the like, the power consumption of the load is large from the work start time to the end time, and the power consumption of the load is small at a time such as night. For this reason, the threshold value 2 is changed from the work start time to the end time to be small and to be small at times such as nighttime in order to set the load operation time by restart after a power failure as a desired time. The control unit 16 instructs the battery control unit 21 to change the threshold 2 via the power supply line 6 by the power line communication unit 7d, so that the threshold 2 changing unit 42 sets the threshold 2 of the threshold 2 comparison unit 20. change.
As described above, the clock unit 45 that counts the current time is provided, and the control unit 16 changes the threshold value 1 and the threshold value 2 in association with the time counted by the clock unit 45, thereby performing load operation by restart after a power failure. The time can be a desired time.

<Sixth Embodiment>
FIG. 8 is a block diagram showing an overall configuration of a power supply system 1F according to the sixth embodiment of the present invention. The same components as those in FIG. In the embodiment of FIG. 8, the display unit 46 that indicates the operating state of the load is provided to the user, and whether the load is in the sleep state, the stopped state, or the operating state is displayed and the operating state of the load is displayed to the user. Therefore, the user can grasp from the display whether the load is operating even during a power failure, whether it is in a sleep state or a stop state, and can perform a necessary operation.
As described above, the display unit 46 that displays the operation state of the load is provided, and the control unit 16 displays the operation state of the load by displaying the sleep state, the stop state, or the operation state on the display unit 46. It can be visually confirmed.

<Other embodiments>
In the first to sixth embodiments, a solar cell has been described as an example of a power generation device that generates power using natural energy. However, according to the present embodiment, the present invention is not limited to a solar cell. For example, it can be used for wind power generators and tidal power generators.
In the first to sixth embodiments, a recording medium that records a program code of software that realizes the function of the power supply system described above is supplied to the system or apparatus. The computer (or CPU (processor), MPU, DSP) of the system or apparatus executes the program code stored in the recording medium.
In this case, the program code itself read from the recording medium realizes the function of the power supply system described above. Recording media for supplying the program code include FD, hard disk, optical disk, magneto-optical disk, CD-ROM, CD-R, magnetic tape, non-volatile memory, optical recording medium such as ROM, magnetic recording medium, optical There are magnetic recording media and semiconductor recording media.

Further, the above-described function of the power supply system is realized by executing the program code read by the computer.
In addition, based on the instruction of the program code, the OS running on the computer may perform part or all of the actual processing, and the function of the power supply system described above may be realized by the processing. included.
The program code read from the recording medium is written into a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer, and then executed based on an instruction of the program code. It goes without saying that the CPU or the like provided therein performs part or all of the actual processing, and the functions of the power supply system described above are realized by the processing.

  Thus, the commercial power source (main power source) 8, the secondary battery 10 that supplies power in place of the commercial power source 8 when power supply from the commercial power source 8 is stopped, and the solar cell (power generation device using natural energy) ) In a power supply system including a regenerative power supply unit 2 that supplies the power generated by 11 to the secondary battery 10 and a remaining power detection unit 18 that detects the remaining power of the secondary battery 10. A control unit 16 that controls the charging / discharging of the secondary battery 10 and the operating state of the load is provided. When the power supply from the commercial power supply 8 is stopped, the control unit 16 reduces the remaining power of the secondary battery 10 to a threshold value 1 or less. In such a case, the load is controlled to be in a sleep state or a stop state. On the other hand, when the remaining power of the secondary battery 10 exceeds the threshold value 2 higher than the threshold value 1 by the power supplied from the regenerative power supply unit 15, the load is controlled so as to be activated and become in an operating state. Thereby, the power consumption of the load can be appropriately controlled in an emergency such as when power supply from the commercial power supply 8 is stopped, and the operation of the load can be continued until the emergency of the commercial power supply 8 is resolved.

  In addition, by causing the processor to execute the control method described above, the power consumption of the load is appropriately controlled in an emergency such as when power supply from the commercial power supply 8 is stopped, and the load until the commercial power supply 8 is resolved in an emergency. Can be continued.

DESCRIPTION OF SYMBOLS 1A-1F ... Power supply system, 2 ... DC power supply part, 3-5 ... Load, 6 ... Power supply line, 7a-7e ... Power communication part, 8 ... Commercial power supply, 9 ... AC / DC converter, 10 ... Two Secondary battery, 11 ... solar battery, 12 ... DC / DC converter, 13 ... charging circuit, 14 ... discharge circuit, 15 ... regenerative power supply unit, 16 ... control unit, 17 ... functional unit, 18 ... remaining power capacity detection unit, DESCRIPTION OF SYMBOLS 19 ... Threshold 1 comparison part, 20 ... Threshold 2 comparison part, 21 ... Battery control part, 22 ... Sleep / stop load control part, 23 ... Power failure detection part, 40 ... Load electric power monitoring part, 41 ... Threshold value 1 change part, 42 ... Threshold 2 changing unit, 43 ... Generated power monitoring unit, 44 ... Power remaining capacity change rate monitoring unit, 45 ... Timing unit, 46 ... Display unit

JP 2009-148209 A

Claims (10)

A power supply system having a main power supply and a secondary battery that supplies power to at least one load device in place of the main power supply when power supply from the main power supply is stopped,
Regenerative power supply means for supplying the secondary battery with power generated by a power generation device using natural energy;
Secondary battery remaining capacity detection means for detecting the remaining power of the secondary battery;
Control means for controlling the operating state of the load device,
When the power supply from the main power supply is stopped, the control means detects the load when the secondary battery remaining capacity detected by the secondary battery remaining capacity detection means falls below a first threshold value. The device is controlled so as to be in a sleep state or a stopped state, and the secondary battery remaining capacity detected by the secondary battery remaining capacity detecting means by the power supplied from the regeneration power supply means is the first threshold value. When the second threshold value higher than the threshold value is exceeded, the power supply system is controlled so as to activate the load device and enter an operating state. The regenerative power supply means, and a power supply line for supplying power from the secondary battery to the load device,
The control means transmits a stop signal to the load device via the power supply line when the remaining power capacity of the secondary battery is equal to or less than a first threshold value, and puts the load device in a sleep state or a stop state. The power supply line when the secondary battery is charged by the power supplied from the regenerative power supply means and the remaining power of the secondary battery exceeds a second threshold value. 2. The power supply system according to claim 1, wherein an activation signal is transmitted to the load device via the control unit to control the load device to be in an operating state. Load power monitoring means for monitoring the power consumption of the load device,
3. The power supply system according to claim 2, wherein the control unit changes the first threshold value or the second threshold value in association with the load power monitored by the load power monitoring unit. Comprising generated power monitoring means for monitoring the generated power of the regenerative power supply means,
3. The power supply system according to claim 2, wherein the control unit changes the first threshold value and the second threshold value in association with the generated power monitored by the generated power monitoring unit. A power remaining capacity change rate monitoring means for monitoring a time change of the power remaining capacity of the secondary battery when power is supplied from the secondary battery to the load device;
3. The power according to claim 2, wherein the control means changes the first threshold value and the second threshold value in association with the remaining power capacity change rate monitored by the remaining power capacity change rate monitoring means. Supply system. It has a clock means to keep the current time,
3. The power supply system according to claim 2, wherein the control means changes the first threshold value and the second threshold value in association with the time measured by the clock means. Comprising display means for displaying the operating state of the load device;
The power supply system according to claim 2, wherein the control unit displays a sleep state, a stopped state, or an operation state on the display unit. A main power supply,
A secondary battery for supplying power instead of the main power supply when power supply from the main power supply is stopped;
Regenerative power supply means for supplying the secondary battery with power generated by a power generation device using natural energy;
A secondary battery remaining capacity detection means for detecting the remaining power of the secondary battery; and a power supply system comprising:
Comprising control means for controlling the operating state of the load device;
When the power supply from the main power supply is stopped, the control means detects the load when the secondary battery remaining capacity detected by the secondary battery remaining capacity detection means falls below a first threshold value. The device is controlled so as to be in a sleep state or a stopped state, and the secondary battery remaining capacity detected by the secondary battery remaining capacity detecting means by the power supplied from the regeneration power supply means is the first threshold value. A control device for a power supply system, wherein when the second threshold value higher than the second threshold value is exceeded, the load device is activated and controlled to be in an operating state. A main power supply,
A secondary battery for supplying power instead of the main power supply when power supply from the main power supply is stopped;
Regenerative power supply means for supplying the secondary battery with power generated by a power generation device using natural energy;
A secondary battery remaining capacity detection means for detecting the remaining power of the secondary battery; and a power supply system comprising:
Comprising a control step for controlling an operating state of the load device;
In the control step, when the power supply from the main power supply is stopped, the load of the secondary battery detected by the secondary battery remaining capacity detection unit is less than or equal to a first threshold value. The device is controlled so as to be in a sleep state or a stopped state, and the secondary battery remaining capacity detected by the secondary battery remaining capacity detecting means by the power supplied from the regeneration power supply means is the first threshold value. A control method for a power supply system, characterized in that when the second threshold value higher than the second threshold value is exceeded, the load device is activated so as to be in an operating state.   A power supply program for causing a processor to execute the steps of the control method according to claim 9.

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