JPH07163058A - Battery life signalling system - Google Patents

Abstract

PURPOSE:To accurately detect a battery life by using a charging electric power variable as a decision reference for a battery life at the time of charging a back-up battery. CONSTITUTION:A back-up battery 15 of a secondary power supply is provided in a primary power supply line composed of a diode 11 and a rectifier part 12. A switch part 1 is provided between the diode 11 and the rectifier 12 part. A diode 13 is provided between the output terminal of the back-up battery 15, and a current detection part 2 and a voltage detection part 16 are provided between the back-up battery 15 and the diode 13. A switch part 14 is provided between the output terminal of the rectifier part 12 and the anode side part of the diode 13. A processing part 5 outputs a control signal for the opening and closing of the respective switches 1, 14 according to the initially charged electric power variable of the back-up battery stored in a memory part 4 and the charged electric power variable obtained from the current detection part 2 and the voltage detection part 16.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery life informing system for a backup power supply circuit having a backup battery as a secondary power supply.

[0002]

2. Description of the Related Art Recently, road-vehicle information systems and PHS (P
personal Handy phone System
When using m), etc., many base stations have been distributed. These information systems are equipped with a backup power supply circuit containing a backup battery as a secondary power supply in order to prevent the system from stopping during a power failure.

FIG. 2 is a block diagram showing a schematic configuration of a backup power supply circuit used in the above information system.

This backup power supply circuit includes a rectifier unit 2
The input end side of 2 is a power supply input line, and the diode 21 is connected in series to the output end side to form a power supply output line. The secondary power supply is connected in series between the output end of the backup battery 25 and the power supply output line. Diode 23 connected to
Is a circuit equipped with.

In the backup power supply circuit, the line on the output end side of the rectifier unit 22 is branched and connected to the backup battery 25 via the switch unit 24. Therefore, the backup battery 25 is opened by opening the switch unit 24.
Is charged. Further, a voltage detection unit 26 is connected to the line between the diode 23 and the backup battery 25. The voltage detection unit 26 monitors the voltage of the power supply line, and when it detects that the charging voltage of the backup battery 25 has reached a voltage indicating the limit of charging (hereinafter, referred to as charge end voltage), the switch unit 24 is turned on. Open.

FIG. 3 is a graph showing the end-of-charge voltage of the battery, in which the voltage between terminals is measured with respect to the charging time. Generally, the end-of-charge voltage is a voltage V that is a predetermined voltage amount ΔV lower than the peak voltage V1 of the inter-terminal voltage in FIG.
Say 2.

In the above-mentioned backup power supply circuit, the voltage applied to the power supply input line is rectified by the rectifier unit 22 and then passed through the diode 21 to be supplied to the main circuit (not shown). At this time, if the switch unit 24 is closed,
The voltage is also supplied to the backup battery 25, and charging of the backup battery 25 is started. Backup battery 25
Is charged and the charging voltage reaches the end-of-charge voltage V2, the voltage detecting unit 26 detects that fact and the switch unit 24 is opened. Here, the charging end voltage V performed by the voltage detection unit 26
In the detection of No. 2, the charging voltage value is detected from the fluctuation amount within a predetermined time.

When the switch section 24 is opened, the voltage supply from the power input line to the backup battery 25 is stopped.

Here, when the power supply from the power input line to the main circuit (not shown) is stopped due to a power failure or the like, the power is supplied to the main circuit (not shown) from the backup battery 25 through the diode 23. As a result, the power supply to the main circuit continues to be supplied without interruption.

When the power failure state is resolved and a voltage is applied to the power supply input line, power is supplied to the main circuit from the rectifier section 22 through the diode 21, and at the same time the switch section 24 is closed. Charging of the backup battery 25 described above is started as described above.

In the above backup power supply circuit,
Normally, the output voltage of the rectifier unit 22 is the backup battery 25.
Although the voltage is set to be higher than the voltage of, the reverse current from the power output line to the backup battery 25 does not occur because the diode 23 is inserted.

Trickle charging is generally known as the above method.

[0013]

SUMMARY OF THE INVENTION An object of the present invention is to accurately determine the amount of charge power when a backup battery is charged, which is a criterion for battery life determination, even if the end-of-charge voltage fluctuates due to temperature and charging conditions. An object of the present invention is to provide a battery life notification system that can notify the battery life.

[0014]

A battery life informing system of the present invention is a battery life informing system of a backup power supply circuit having a rectifier for supplying a primary power source and a backup battery for supplying a secondary power source. A voltage detecting means for detecting the voltage of the battery, a current detecting means for detecting the charging current of the backup battery, and a storage section in which the initial charging electric energy of the backup battery is stored,
The charging means for the backup battery and the power supply state by either the primary power source or the secondary power source and the charging state by the charging means are controlled according to the detection results of the voltage detecting means and the current detecting means, and A control means for notifying the life of the backup battery based on a charging result, and when the power supply by the secondary power source is performed, the control means supplies power until the backup battery output reaches a predetermined voltage. Supply is performed, after which charging by the charging means is started, the charging power amount is calculated from the voltage and the charging current, and the charging power amount is higher than the initial charging power amount stored in the storage unit. It is characterized in that the backup battery is judged to have reached the end of its life when the ratio is below a certain ratio.

In the battery life notification system, the backup battery has a first switch in the line for supplying the primary power source, and the control means controls ON / OFF of the first switch. Is discharged to a predetermined voltage.

Further, the control means is characterized in that the on / off of the first switch is controlled to discharge the backup battery at a specific cycle.

In the battery life notification system, a second switch is provided in the line where the voltage is supplied to the backup battery, and the control means switches the switch when the voltage detecting means detects the end-of-charge voltage. It is characterized by opening.

[0018]

In the present invention configured as described above, when charging is performed, first, a voltage (hereinafter referred to as a cutoff voltage) indicating a limit at which charging / discharging of the backup battery at the time of power failure is terminated by the determination means. ) Until.

Here, when the power supply is switched and the charging of the backup battery is started, the voltage detecting means and the voltage detecting means detect the charging voltage and the charging current of the backup battery and output the detection result to the judging means. The judging means is
The charging power amount of the backup battery is calculated from the input charging voltage, charging current and time required for charging. Further, the calculated amount of charge power is compared with the initial amount of charge power stored in advance in the storage unit to obtain the amount of decrease in the amount of charge power. When the calculated drop amount exceeds a predetermined value,
A notification signal is output from the determination means to notify the life of the backup battery.

Further, in the above-mentioned battery notification system, the first switch is provided in the regular power supply line, and the second switch is further provided in the power supply line to the backup battery. In this case, when the backup battery starts to be discharged due to a power outage or the like, the determining means determines the first and second
Turn off both switches. When the voltage detection means detects that the discharge voltage of the backup battery has reached the final voltage, the determination means turns on both the first and second switches to start charging the backup battery.

The above-mentioned first switch is opened by the judging means at a specific cycle. Therefore, even if the power failure has not occurred for a long period of time, the battery life is determined at regular intervals.

As described above, according to the present invention, since the backup battery is discharged to the final voltage and then recharged to calculate the charging power amount, the battery life can be accurately determined. Moreover, since the battery life is determined by the amount of charging power, even if the final charging voltage changes depending on the temperature, the charging status, etc., the battery life will not be erroneously determined. Further, since the backup battery is completely discharged at regular intervals, battery life will not be erroneously determined due to deterioration of battery capacity due to repeated charging (hereinafter referred to as memory effect).

[0023]

Embodiments of the present invention will now be described with reference to the drawings.

FIG. 1 is a block diagram showing a schematic configuration of a battery life notification system according to an embodiment of the present invention.

The battery life notification system detects the battery life of the backup power supply circuit. The configuration is such that the input end side of the rectifier unit 12 is the power supply input line and the output end side is connected with the diode 11 in series to form the power supply output line, and the output end of the backup battery 15 which is the secondary power supply and the power supply output. A diode 13 connected in series with the line is provided.

In the battery life notification system, the switch unit 1 for controlling the discharge state of the backup battery 15 is provided between the diode 11 and the rectifier unit 12, and the switch unit 1 is provided between the backup battery 15 and the diode 13. A current detector 2 is provided. The switch unit 14 is provided between the output end of the rectifier unit 12 and the anode side portion of the diode 13 in order to control the state of charge of the backup battery 15. The voltage detection unit 16 monitors the output voltage of the backup power supply 15, and its detection output is sent to the processing unit 5 together with the detection output of the current detection unit 2.

The processing section 5 constitutes the control section 3 together with the timer section 6, and the initial charging power amount of the backup battery stored in the storage section 4 and the respective detection outputs of the current detection section 2 and the voltage detection section 16. Depending on the above,
A signal for controlling the open / closed state of 14 is output.

Next, the specific operation of this embodiment will be described.

In the battery life notification system of FIG. 1, the voltage applied to the power supply input line is rectified by the rectifier unit 12 and then supplied to the main circuit (not shown) via the switch unit 2 and the diode 11. At this time, if the voltage is not applied to the power input line due to a power failure or the like, the voltage is supplied to the main circuit from the backup battery 15 via the diode 13. The backup battery 15 supplies voltage to the main circuit by the backup battery 1.
This is performed until the discharge voltage of 5 reaches the final voltage.

The backup circuit of this embodiment has a PH
It is provided for a device such as PS that may be momentarily cut off in power supply, and is set so that a power failure does not occur until the discharge of the backup battery falls below the final voltage.

When the power supply from the backup battery 15 is started, the processing unit 5 turns off both the switch units 1 and 14, and at the same time, the voltage detection unit 16 detects the discharge voltage and outputs the detection result to the processing unit 5. Output.

Even if the power failure is eliminated, the above-mentioned state is continuously maintained until the voltage detecting section 16 detects that the discharge voltage has reached the final voltage. When the voltage detection unit 16 detects that the discharge voltage has reached the final voltage, the detection processing unit 5 turns on both the switch units 1 and 14. As a result, the voltage is supplied to the main circuit via the power supply input line, and at the same time, the voltage is supplied to the backup battery 15 to start charging.

When the charging of the backup battery 15 is started, the voltage detector 16 and the current detector 2 detect the charging voltage and the charging current at that time, and output the detection results to the processor 5, respectively. The processing unit 5 starts counting the charging time using the timer unit 6 at the same time when the detection result is input, and accumulates the detection result. After the charging is started, the voltage detection unit 16 detects the end-of-charge voltage of the backup battery 16 and outputs it to the processing unit 5, and the processing unit 5 turns off the switch unit 14 to charge the backup battery 15. And the count of the timer unit 6 is stopped and the charging power amount during this period is calculated.

The battery life of the backup battery 15 is determined by comparing the charging power amount obtained as described above with the initial charging power amount stored in the storage unit 4. That is, when the calculated charging power amount is equal to or less than the predetermined ratio with respect to the initial charging power, the processing unit 5 determines that the backup battery has reached the end of its life, and outputs a signal to that effect.

In the battery life notification system described above, the backup battery 15 cannot be charged / discharged unless the power supply to the power input line is interrupted for a long period of time such as a power failure. It becomes difficult to judge. Therefore, the switch unit 2 is used to forcibly cut off the power supply from the power input line to the main circuit. As a result, the backup battery 15 can be discharged, and the life of the backup battery 15 can be determined by closing the switch unit 2 after a predetermined time and measuring the charging power amount at the time of recharging. The processing unit 5 opens the switch unit 2 at a specific cycle.

Note that the battery life determination as described above can effectively determine the battery life even when the accurate recharge electric energy cannot be measured due to the memory effect.

Although V2 in FIG. 3 is detected as the end-of-charge voltage of the backup battery 15, it is more preferable to detect ΔV in the same figure.

Further, instead of the switch 14 for controlling the voltage supply to the backup battery 15, a diode may be used in one line.

[0039]

As described above, when the battery life notification system of the present invention is used, the battery life is determined by measuring the decrease in the amount of recharged electric power of the battery, so that it depends on the temperature and the charging condition. It is possible to prevent erroneous determination of battery life.

Further, there is an effect that the capacity deterioration of the backup battery due to the memory effect is reduced.

Furthermore, since the timing of battery replacement becomes clear, there is an effect that the cost for the maintenance can be reduced.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of a battery life notification system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a schematic configuration of a backup power supply circuit.

FIG. 3 is a graph showing the end-of-charge voltage of the battery.

[Explanation of symbols]

 1, 14, 24 Switch unit 2, Current detection unit 3 Control unit 4 Storage unit 5 Processing unit 6 Timer unit 11, 13, 21, 23 Diode 12, 22 Rectifier unit 15, 25 Backup battery 16, 26 Voltage detection unit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G06F 1/28

Claims (4)

[Claims] 1. A battery life notification system for a backup power supply circuit comprising a rectifier for supplying a primary power source and a backup battery for supplying a secondary power source, voltage detecting means for detecting a voltage of the backup battery, and the backup. A current detection unit that detects a charging current of a battery, a storage unit that stores the initial charging power amount of the backup battery, a charging unit of the backup battery, and a power supplied from either the primary power supply or the secondary power supply. While controlling the supply state and the charging state by the charging means according to the detection result of the voltage detecting means and the current detecting means, and having a control means for notifying the life of the backup battery based on the charging result, The control means sets the backup battery output to a predetermined value when the power is supplied from the secondary power source. Electric power is supplied until it reaches a voltage, after which charging by the charging means is started, and a charging power amount is calculated from the voltage and the charging current, and the charging power amount is initially stored in the storage unit. The battery life notification system is characterized in that the backup battery is judged to have reached the end of its life if the charging power is less than a certain ratio. 2. The battery life notification system according to claim 1, further comprising a first switch in the line for supplying the primary power source, and the control means controls ON / OFF of the first switch. The battery life notification system is characterized by discharging the backup battery to a predetermined voltage. 3. The battery life notification system according to claim 2, wherein the control means controls ON / OFF of the first switch,
A battery life notification system characterized in that the backup battery is discharged at a specific cycle. 4. The battery life notification system according to claim 1, further comprising a second switch in a line to which a voltage is supplied to the backup battery, wherein the control means detects when the voltage detection means detects the end-of-charge voltage. In addition, the battery life notification system is characterized in that the switch is opened.