JP2003009423A - Decision method and equipment of battery life - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a decision method and equipment of a battery life which decides the battery life of a UPS system accurately. SOLUTION: A small capacity battery 5 for life time decision is installed in advance under the identical environment with the battery 4 for power supply by the same method as the battery 4 for power supply. Normally the battery 5 for life time decision is charged and discharged simultaneously with the battery 4 for power supply. In the power failure the battery 5 for lifetime decision starts to discharge simultaneously with the battery 4 for power supply and continues discharging until the discharge voltage becomes equal to the predetermined threshold voltage even when the power failure is recovered and the recharging of the battery 4 for power supply is started. A logic part 6 measures the discharge time from the discharge starting time to the time when the discharge voltage becomes equal to the predetermined threshold voltage. A lifetime decision part 7 decides that the battery for power supply comes to the exchange time when the discharge time is shorter than the predetermined threshold discharge time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for determining battery life of an uninterruptible power supply device that supplies backup power to a device such as a computer that does not allow power failure.

[0002]

2. Description of the Related Art An uninterruptible power supply system has a function of supplying power to a target device in place of a commercial power supply in case of a power failure. How long the backup power supply is required at the time of power failure depends on the user. The user selects the uninterruptible power supply from his own requirements.

A battery is provided inside the uninterruptible power supply as a DC energy source. The capacity of the battery determines the power supply capacity of the uninterruptible power supply.
The battery gradually deteriorates due to repeated charging / discharging and the like, and the discharge voltage decreases, or the time during which discharge above a predetermined voltage can be maintained becomes shorter. Then, the battery will eventually fail to fulfill its function. When or before the uninterruptible power supply is no longer fully functional, the user needs to replace the uninterruptible power supply.

A recommended number of days for replacement is set for the uninterruptible power supply, and the user generally determines the replacement time by referring to the period. That is, the user determines the replacement time by adding the recommended number of replacement days to the date of manufacture of the uninterruptible power supply.

However, since the life of the battery varies greatly depending on the use environment and the number of discharges, the recommended number of replacement days does not always match the original life of the battery. The recommended number of replacement days is usually set assuming a somewhat strict operating environment, and thus is often shorter than the actual life. Further, if it is used in a more severe environment, it may be expected that the life will come earlier than the recommended replacement days.

From these things, it is desired to accurately judge the life of the uninterruptible power supply.

Japanese Patent Laid-Open No. 2000-350384 discloses that
There is described an uninterruptible power supply device that determines whether or not it is time to replace the battery by comparing the voltage at the start of discharge of the energy storage unit with a preset value (abnormal voltage value). If the voltage at the start of discharge is equal to or lower than the abnormal voltage value, the uninterruptible power supply determines that it is about to be replaced and issues a warning. Also,
Based on the preset storage battery discharge voltage characteristic curve, the uninterruptible power supply device gives advance notice of a voltage shortage or stops the trip if the discharge voltage drops to a predetermined value during discharging.

[0008]

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention
The uninterruptible power supply device described in Japanese Patent No. 384 determines that the replacement time is near, based only on the voltage at the start of discharge.

However, the backup time required for the uninterruptible power supply differs depending on each user. Even if it is determined that the uninterruptible power supply itself is about to be replaced, the backup time required by the user may still be satisfied. That is, in this conventional example, even if it is determined that the uninterruptible power supply itself is about to be replaced, some users may not need to replace the uninterruptible power supply.

An object of the present invention is to provide a battery life determining method and apparatus for accurately determining the life of a battery of an uninterruptible power supply.

[0011]

In order to achieve the above object, the battery life judging method of the present invention is a battery life judging method for judging the life of a battery for power supply of an uninterruptible power supply. A battery for life judgment having a small capacity and the same method as the battery for power supply is previously provided in the same environment as the battery for power supply, and normally, the battery for life judgment is charged in accordance with the battery for power supply. When the battery for discharging is discharged and the battery for power supply is started to discharge at the same time as the battery for power supply, and the battery for power supply is started to be recharged after the power failure is restored, the battery for life determination is discharged. The discharge voltage is maintained until the discharge voltage reaches a predetermined voltage threshold value, and the discharge time from the start of discharge until the discharge voltage reaches the voltage threshold value is measured. During it is determined that the power supply battery is shorter than a predetermined discharge time threshold it has come to change time.

Therefore, since the replacement time is determined by the discharge time threshold value, the discharge time threshold value is selected to obtain an appropriate replacement time that matches the time desired to be backed up by the uninterruptible power supply.

According to an embodiment of the present invention, when the discharge time is equal to or more than the discharge time threshold value, the discharge time measured in an uninterruptible power supply device used in the past in an environment equivalent to that of the uninterruptible power supply device. Predict the replacement time from the data of
The remaining life of the power supply battery is predicted from the discharge time measured in the uninterruptible power supply currently in use and the data measured in the uninterruptible power supply used in the past.

Therefore, the change in the power supply capacity of the battery for life judgment, which has the same method as that of the battery for power supply and is placed under the same use condition, is compared with the data of the uninterruptible power supply unit used in the past under the same condition. By comparing, the life of the power supply battery is predicted.

According to another embodiment of the present invention, when the discharge time is equal to or longer than the discharge time threshold value, the replacement time and the remaining life are predicted from the change in the discharge time measured so far.

According to another embodiment of the present invention, when the discharge time is equal to or longer than the discharge time threshold value, measurement is performed in an uninterruptible power supply device used in the past in an environment equivalent to that of the uninterruptible power supply device. If there is data of the discharged time, the replacement time is predicted from the data, and the remaining life of the power supply battery is predicted from the data and the discharge time measured in the uninterruptible power supply currently in use. If the data is not available, the replacement time and the remaining life are predicted from the change in the discharge time measured so far in the uninterruptible power supply currently in use.

According to an embodiment of the present invention, the voltage threshold value can be set by the user.

According to an embodiment of the present invention, the discharge time threshold value can be set by the user.

The battery life judging device of the present invention is a battery life judging device for judging the life of the power supply battery of the uninterruptible power supply, and has the same system as the power supply battery and is provided under the same environment. It is charged and discharged in accordance with the power supply battery at normal time, starts discharging at the same time as the power supply battery at the time of power failure, and even if the power failure is restored and the recharge of the power supply battery is started, A small-capacity battery for life judgment that continues discharging until the discharge voltage reaches a predetermined voltage threshold, and a discharge time from the start of discharge of the battery for life judgment until the discharge voltage reaches the voltage threshold. The logic part to measure,
The battery pack has a life determining unit that determines that the power supply battery is about to be replaced when the discharge time is shorter than a predetermined discharge time threshold value.

According to an embodiment of the present invention, the life determining unit determines the uninterruptible power supply used in the past in an environment equivalent to the uninterruptible power supply when the discharge time is equal to or longer than the discharge time threshold value. Predict the replacement time from the data of the discharge time measured in the device, the discharge time measured in the uninterruptible power supply currently used, and from the data measured in the uninterruptible power supply used in the past, the Predict the remaining life of the power supply battery.

According to another embodiment of the present invention, when the discharge time is equal to or longer than the discharge time threshold, the life determining unit determines the replacement time and the remaining time from the change in the discharge time measured so far. Predict the lifespan of.

According to another embodiment of the present invention, the life judging section has used in the past in an environment equivalent to the uninterruptible power supply when the discharge time is equal to or longer than the discharge time threshold value. If there is discharge time data measured in the uninterruptible power supply, the replacement time is predicted from the data, and the discharge time measured in the uninterruptible power supply currently in use is used to estimate the battery for power supply. The remaining life is predicted, and if the data is not available, the replacement time and the remaining life are predicted from the change in the discharge time measured so far in the uninterruptible power supply currently in use.

According to the embodiment of the present invention, in the battery life determining device, the voltage threshold value can be set by the user.

According to the embodiment of the present invention, in the battery life determining apparatus, the discharge time threshold value can be set by the user.

[0025]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the uninterruptible power supply system of this embodiment.

Referring to FIG. 1, the uninterruptible power supply system of this embodiment has an uninterruptible power supply 1, a processing device 2 and a display device 3.

The uninterruptible power supply 1 has a power supply battery 4, a life determining battery 5, and a logic section 6.

The power supply battery 4 is a battery having a predetermined capacity for supplying backup power to a target device (not shown).

The battery 5 for life judgment is a battery for judging the life of the battery 4 for power supply, and is a small capacity battery of the same system as the battery 4 for power supply.
The battery 5 for life judgment is in the uninterruptible power supply 1 in order to have the same environment as the battery 4 for power supply, and is normally charged and discharged together with the battery 4 for power supply.

In the event of a power failure, the battery 5 for life judgment is also used.
Starts discharging according to the power supply battery 4, and continues discharging until the discharge voltage reaches a predetermined voltage even after the power failure is restored and the recharge of the power supply battery 4 is started. The predetermined voltage is the lowest voltage (hereinafter, referred to as a voltage threshold) at which the target device to which power is supplied can operate.
The battery 5 for life judgment is recharged after the discharge voltage falls below this predetermined voltage.

The logic unit 6 measures the discharge voltage of the life determining battery 5 and the time from the start of discharge until the discharge voltage becomes equal to or lower than the voltage threshold (hereinafter referred to as discharge time). The voltage threshold can be set in the logic unit 6 by the user.

The processing device 2 includes a life judging section 7, a threshold value storage section 8, a measured data storage section 9 and a past data storage section 10.
have.

The threshold value storage unit 8 stores a predetermined threshold value of discharge time (hereinafter, referred to as discharge time threshold value). The discharge time threshold value is a value that can be set by the user, and is a threshold value for determining the replacement time of the uninterruptible power supply 1. If the discharge time of the life determining battery 5 is shorter than the discharge time threshold value, it is determined that the uninterruptible power supply 1 is about to be replaced. The user sets a desired time for supplying power from the uninterruptible power supply 1 to the target device.

The measurement data storage unit 9 is used for the uninterruptible power supply unit 1.
The discharge voltage and discharge time data (hereinafter, referred to as measurement data) measured by the logic unit 6 are stored. The measurement data storage unit 9 also stores the manufacturing date of the uninterruptible power supply 1 and the recommended number of replacement days in the measurement data.

The past data storage unit 10 stores discharge voltage and discharge time data (hereinafter referred to as past data) measured by an uninterruptible power supply device that has been used in the same environment in the past. The past data can be input by the user. If the user does not have past data, the user does not need to input it. In that case, the user sets that there is no past data. It should be noted that the past data includes the manufacturing date of the uninterruptible power supply device that measured the past data and the recommended number of replacement days.

The life judging section 7 records the data measured by the logic section 6 in the measurement data storage section 9. In addition, the life determining unit 7 determines whether or not it is the replacement time based on the data measured by the logic unit 6 and the discharge time threshold value stored in the threshold value storage unit 8. Furthermore, the life determination unit 7 predicts the life of the uninterruptible power supply 1 based on the data stored in the past data storage unit 10 and determines the recommended replacement date. In addition, when there is no past data, the life judging unit 7 determines the recommended replacement date from the measurement data of the uninterruptible power supply 1 currently in use.

The display device 3 displays the management screen 11 according to an instruction from the life determining section 7. The management screen 11 is a screen displayed for the user to manage the life of the uninterruptible power supply 1.

The operation of the uninterruptible power supply system of this embodiment will be described. FIG. 2 is a flowchart showing the operation of the uninterruptible power supply system of this embodiment.

Before using the uninterruptible power supply 1, the user charges the power supply battery 4 and the life judgment battery 5 in advance. At that time, it is desirable that each battery be fully charged.

Referring to FIG. 2, first, each basic data is set by the user (step 101). That is, a voltage threshold value is set in the logic section 6 and a discharge time threshold value is set in the threshold value storage section 8. If there is past data, it is recorded in the past data storage unit 10. Further, the manufacturing date of the uninterruptible power supply 1 and the recommended number of replacement days are set in the measurement data storage unit 9.

If there is a power failure, the discharge time is measured by the logic unit 6 and the life judgment unit 7 is notified (step 102).

The discharge time notified to the life judging section 7 is recorded in the measurement data storage section 8 by the life judging section 7 (step 103).

Next, the life determining section 7 compares the discharge time with the discharge time threshold value (step 104).

If the discharge time is shorter than the discharge time threshold value, it means that the replacement time has already passed, and therefore the management screen 1 of the display device 3 is instructed by the instruction of the life judging section 7.
The replacement instruction is displayed in step 1 (step 105), and the process returns to step 102.

When the discharge time is equal to or longer than the discharge time threshold value, the life determining unit 7 determines whether or not there is past data in the past data storage unit 10 (step 106).

When there is no past data in the past data storage unit 10, the predicted replacement date obtained from the measurement data by the life determining unit 7 is displayed on the management screen 11 (step 107) and the process returns to step 102. The predicted replacement date is the date predicted to be the replacement time.

When obtaining the estimated exchange date from the measured data,
If the measurement data storage unit 9 has a plurality of measurement results, the replacement predicted date obtained from the graph showing the transition of the discharge time is displayed. If the measurement data storage unit 9 does not have a plurality of measurement results, the predicted replacement date in which the recommended number of replacement days is added to the preset manufacturing date is displayed.

When there is past data in the past data storage unit 10, the predicted replacement date obtained by the life judging unit 7 from the measured data and the past data is displayed on the management screen 11 (step 108) and the process returns to step 102. At this time, the life judging unit 7 obtains the predicted replacement date from the past data, and the remaining life can be known from which time point in the past data the latest measurement result of the discharge time corresponds.

The uninterruptible power supply system according to the present embodiment has the life determining unit 7 regardless of whether or not there is past data.
The estimated exchange date may be obtained from the measurement data at. In this case, past data is unnecessary.

Further, the uninterruptible power supply system of the present embodiment is assumed to always have past data or data corresponding thereto, and the life judgment unit 7 is determined from the measured data and past data.
It is also possible to calculate the predicted replacement date with.

An example of a method for obtaining the predicted replacement date from a plurality of measurement results will be described in detail.

FIG. 3 is a diagram for explaining a method of obtaining a predicted replacement date from a plurality of measurement results in the uninterruptible power supply system of this embodiment. In FIG. 3, the vertical axis represents the measured discharge time t1 (minutes), and the horizontal axis represents the usage period t2 (days) from the start of use to the present. Measurement points A, B,
C and D are points indicating the measurement results recorded as the measurement data. The measurement point D shows the latest measurement result. Further, the discharge time threshold value is shown by a straight line t1 = Y.

The use period t2 at the point where the straight line CD in FIG. 3 intersects with the straight line t1 = Y is set as the predicted replacement date of the uninterruptible power supply 1. That is, the remaining life until the predicted replacement date is the period X in FIG.

As another method, straight line AB and straight line B
The envelope of C and the straight line CD is obtained, and the envelope and the straight line t1
The point of intersection with = Y may be the predicted exchange date.

An example of a method for obtaining the predicted exchange date from the past data and the measurement data will be described in detail.

FIG. 4 is a diagram for explaining a method of obtaining a predicted exchange date from past data and measurement data. In FIG. 4, the vertical axis represents the measured discharge time t1.
(Minutes), and the horizontal axis is the usage period t2 (days) from the start of use to the present. The measurement points A, B, C and D are points indicating the measurement results recorded as past data. Further, the discharge time threshold value is shown by a straight line t1 = Y. The latest measurement result of the uninterruptible power supply device 1 currently in use is the discharge time y1.

The intersection of the broken line of the past data passing through the measurement points A, B, C and D and the straight line t1 = y1 is obtained. The usage period t2 at the point where the straight line including the intersection intersects with the straight line t1 = Y is set as the predicted replacement date of the uninterruptible power supply 1. In FIG. 4, since the straight line t1 = y1 intersects the straight line BC, the straight line BC
Is extended and the use period t2 at the point intersecting the straight line t1 = Y is the predicted replacement date. That is, the remaining life until the predicted replacement date is the period X in FIG.

As another method, straight line AB and straight line B
The envelope of C and the straight line CD is obtained, and the envelope and the straight line t1
The use period t2 at the intersection with = Y may be the predicted exchange date.

According to the present embodiment, since the replacement time is determined by the discharge time threshold value which can be set by the user, the time to be backed up by the uninterruptible power supply for each user in consideration of various power supply circumstances in Japan and overseas. It is possible to know the appropriate time to replace the uninterruptible power supply. Various uses such as when the power supply situation is bad and a backup for a relatively long time is required for the uninterruptible power supply, or when a backup for a relatively short time is required to eliminate the effect of noise that occurs when there is a momentary interruption or switching of the main power supply. The replacement time can be determined according to the purpose.

Further, it is the same system as the power supply battery 4, and the change in the power supply capacity of the battery 5 for life judgment under the same use condition is changed by the uninterruptible power supply device used in the past under the same condition. Since the replacement time of the uninterruptible power supply 1 is predicted by comparing with the data, it is possible to appropriately predict the replacement time of the uninterruptible power supply, which greatly differs depending on the usage environment.

When there are a plurality of past data, the average of them may be used. According to this, it becomes possible to eliminate the variation factor of the discharge time due to the sudden change of the situation, and it is possible to obtain a more accurate expected replacement date.

When the uninterruptible power supply is used in a place where the operating environment such as temperature changes greatly depending on the season,
You may use the near past data of the used date. According to this, the historical date measured in the usage environment as close as possible to the present time makes the calculation of the predicted replacement date more accurate.

Further, the processing device 2 of this embodiment may be an information processing device in which the processor executes the application program having the processing of the life judging section 7.

Further, the processing device 2 and the display device 3 of this embodiment may be provided in the uninterruptible power supply 1. in this case,
It is considered that a simple display such as an LCD screen is suitable for the display of the display device 3. This is a configuration suitable for pre-installing the application program, and can simplify the work at startup.

[0066]

According to the present invention, since the replacement time is determined by the discharge time threshold, by selecting the discharge time threshold, it is possible to select an appropriate time in accordance with the time to be backed up by the uninterruptible power supply. You can know when to replace.
Various uses such as when the power supply situation is bad and a backup for a relatively long time is required for the uninterruptible power supply, or when a backup for a relatively short time is required to eliminate the effect of noise that occurs when there is a momentary interruption or switching of the main power supply. The replacement time can be determined according to the purpose.

In addition, the change in the power supply capacity of the battery for life judgment, which is the same method as that of the battery for power supply and placed under the same use condition, is compared with the data of the uninterruptible power supply unit used in the past under the same condition. Since the life of the power supply battery is predicted by comparison, it is possible to appropriately predict the replacement timing that greatly differs depending on the usage environment.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an uninterruptible power supply system according to an embodiment.

FIG. 2 is a flowchart showing the operation of the uninterruptible power supply system of this embodiment.

FIG. 3 is a diagram for explaining a method of obtaining a predicted replacement date from a plurality of measurement results in the uninterruptible power supply system of this embodiment.

FIG. 4 is a diagram for explaining a method of obtaining a predicted exchange date from past data and measurement data.

[Explanation of symbols]

1 uninterruptible power supply 2 processing equipment 3 display devices Battery for power supply 5 Life judgment battery 6 logic section 7 Life judgment part 8 threshold storage 9 Measurement data storage 10 Past data storage 11 Management screen 101-108 steps

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Claims (12)

[Claims] 1. A battery life determining method for determining the life of a power supply battery of an uninterruptible power supply, wherein a small capacity life determining battery is previously supplied in the same manner as the power supply battery. Provided in the same environment as the power supply battery, and normally, the life determination battery is charged and discharged according to the power supply battery, and at the time of a power failure, the life determination battery is discharged at the same time as the power supply battery. Even after the power failure is restored and the recharging of the power supply battery is started, the battery for life determination is continuously discharged until its discharge voltage reaches a predetermined voltage threshold, and The discharge time until the discharge voltage reaches the voltage threshold value is measured, and when the discharge time is shorter than a predetermined discharge time threshold value, the power supply battery is replaced. It is determined that has come in the period, battery life judging method. 2. When the discharge time is equal to or greater than the discharge time threshold value, the replacement time is predicted from discharge time data measured in an uninterruptible power supply device used in the past in an environment equivalent to the uninterruptible power supply device. Then, from the discharge time measured in the uninterruptible power supply currently used, and the data measured in the uninterruptible power supply used in the past, predict the remaining life of the battery for power supply, Item 1. A battery life judging method according to item 1. 3. The battery life determining method according to claim 1, wherein when the discharge time is equal to or more than the discharge time threshold value, the replacement time and the remaining life are predicted from the change in the discharge time measured so far. . 4. When the discharge time is equal to or more than the discharge time threshold value, if there is discharge time data measured in an uninterruptible power supply device used in the past in an environment equivalent to the uninterruptible power supply device, Predict the replacement time from the data, predict the remaining life of the battery for power supply from the data and the discharge time measured in the uninterruptible power supply currently in use, if there is no data, currently in use 2. The battery life determination method according to claim 1, wherein the replacement time and the remaining life are predicted from the change in the discharge time measured so far in the uninterruptible power supply. 5. The battery life judging method according to claim 1, wherein the voltage threshold value can be set by a user. 6. The battery life judging method according to claim 1, wherein the discharge time threshold value can be set by a user. 7. A battery life judging device for judging the life of a power supply battery of an uninterruptible power supply, which is of the same system as the power supply battery, is provided in the same environment, and is normally supplied with the power supply. The battery is charged and discharged in accordance with the power supply battery, and at the time of a power failure, discharge is started at the same time as the power supply battery, and even if the power failure is restored and recharge of the power supply battery is started, the discharge voltage remains the predetermined voltage. A small capacity life determining battery that continues discharging until a threshold value is reached, and a logic unit that measures the discharge time from the start of discharging the life determining battery until the discharge voltage reaches the voltage threshold value, A battery life determining device having a life determining unit that determines that the power supply battery is about to be replaced when the discharge time is shorter than a predetermined discharge time threshold value. 8. The life determining unit determines, when the discharge time is equal to or more than the discharge time threshold value, the discharge time measured in an uninterruptible power supply device used in the past in an environment equivalent to the uninterruptible power supply device. Predict the replacement time from the data, the discharge time measured in the uninterruptible power supply currently in use, and the data measured in the uninterruptible power supply used in the past, the remaining of the battery for power supply The battery life judging device according to claim 7, which predicts a life. 9. The life judgment unit predicts the replacement time and the remaining life from the change in the discharge time measured so far when the discharge time is equal to or longer than the discharge time threshold value. The battery life determination device described. 10. The life determining unit determines, when the discharge time is equal to or more than the discharge time threshold value, a discharge time measured by an uninterruptible power supply device used in the past in an environment equivalent to the uninterruptible power supply device. If there is data, predict the replacement time from the data, predict the remaining life of the battery for power supply from the data and the discharge time measured in the uninterruptible power supply currently in use, the data is If not, the battery life determination device according to claim 7, wherein the replacement time and the remaining life are predicted from the change in the discharge time measured so far in the uninterruptible power supply currently in use. 11. The battery life judging device according to claim 7, wherein the voltage threshold value can be set by a user. 12. The battery life determination device according to claim 7, wherein the discharge time threshold value can be set by a user.