JP2727543B2 - Apparatus having space for storing batteries - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention is suitable for use in portable video equipment and the like.
It consists of a rechargeable battery and a device with its storage space.
Device having a space for storing a battery. [Summary of the Invention] The present invention has a rechargeable battery and a storage space for the battery.
A battery device with a non-volatile memory comprising
A non-volatile memory is provided on the battery side, and this non-volatile memory
From discharge characteristics and discharge characteristics measured at each predetermined number of charges
The calculated battery capacity is stored and stored.
Automatic measurement means centering on the CPU
If the battery is stored in the storage space
The terminal voltage of the non-volatile memory
Discharge obtained from the last stored discharge characteristic measurement
Calculates and displays remaining amount based on data such as characteristics and capacity
To be able to use batteries economically and efficiently.
It realizes the use. [Prior art] Conventionally, portable video equipment, in particular, is used outdoors.
Power supply.
Nickel cadmium battery cells called cadmium batteries
Connect batteries (for example, 10 to 20) in series
Packed ones are used. This NiCad battery is electrically and structurally shown below.
Features (a) to (h), easy to handle
Is known as such. (A) Charge and discharge more than 500 times. (B) The internal resistance is very small, and large current discharge is possible.
Low voltage fluctuation during power supply. (C) Relatively resistant to overdischarge and overcharge. (D) Since the structure is completely sealed, there is little decrease in electrolyte.
No. (E) There is no restriction on the mounting direction of the battery. (F) Long-term storage is possible. (G) Can be used in a wide range of temperature and humidity. (H) Some types are compatible with dry batteries. The life of a NiCad battery with these features is generally
Battery capacity drops below 50% of its nominal value and does not recover
When the capacity is reduced to 50% or less,
It is managed to discard and use a new one. [Problems to be Solved by the Invention] By the way, broadcasting stations, etc.
And manage the life of each battery individually
Is a very cumbersome and administrative problem. An example
For example, in the past, the user has
The number of charging times is recorded, and this charging frequency table is attached to the battery,
Use the battery until the specified number of charges is reached, or
Charge the battery using a personal computer, etc.
There is a way to centrally manage the numbers for each battery.
Was. Also, simply use it from the start date of use to the specified period
And how to dispose of batteries regardless of their condition.
Had been. However, in any of the above methods,
Charging times and usage without accurately knowing the battery capacity.
Is it economical to judge the battery life only during the service period?
There was a drawback that could not be managed efficiently. Therefore, it is an object of the present invention to determine an accurate battery capacity.
As well as easily predict the battery life.
Enables economical and efficient use of batteries
A device that has a space for storing batteries
To provide. Also, as mentioned above, portable video equipment
The battery is often used in
When it becomes unusable, it becomes difficult to continue photographing and the like.
Therefore, in the past, the terminal voltage of the battery was
Lights a warning lamp etc. when is below a predetermined level
Before the battery completely becomes inoperable.
You are taking action. However, in the conventional method, the remaining
Inability to predict the amount and manage the battery effectively
There is a point, therefore, the remaining time when the battery in use can be used
It is necessary to have a device with a function that can easily and accurately grasp the interval.
Is desired. Therefore, another object of the present invention is to use a battery in use.
Easy and accurate grasp of available remaining time, battery management
A device that has a space for storing batteries to facilitate
To provide. [Means for Solving the Problems] The first invention is a rechargeable battery having a built-in nonvolatile memory.
Device with space for storing
Of the battery for a predetermined time, measure the terminal voltage of the battery,
After the fixed load, disconnect the load from the battery and measure the load.
Discharge characteristics data and capacity data of the battery
Memory, and read from the nonvolatile memory
Total usage time or total usage from battery performance data and battery terminal voltage
Calculate the volume and read the capacity data read from the nonvolatile memory.
Battery usage time or total usage amount
Calculate the remaining time or remaining amount and use it for the device where the battery is stored
Characterized by having means for displaying the remaining time or remaining amount.
Stores rechargeable batteries with built-in non-volatile memory
This is a device having a space to be used. A second invention is a battery
Means for displaying the remaining usage time or remaining amount on the display means
Nonvolatile memory and display means,
Has a space to store the provided rechargeable battery
Device. [Operation] When the nonvolatile memory 3 is provided in the battery pack 1,
In addition, for example, an automatic measurement centering on the CPU 14 is provided on the charging device 7 side.
Setting means is provided. The space stored in the battery pack 1
CPU 14 automatically shuts down when stored in
Reads the charge count data stored in the memory 3
Then, the number of times of charging is displayed on the display unit 19. And selectively
When the charging mode is set, the charge mode is set based on the value of the temperature sensor 12.
To operate the heater 21 and the cooler 22,
The charging circuit 16 with the ambient temperature of 1 controlled to the optimum one
Is connected to the battery group 2 to perform charging. Terminal voltage of battery group 2
Monitor the value of the voltage and drop the voltage above a certain level.
Is detected, charging is terminated and a flag indicating the number of charging
Is updated, and the charge count data and the like are stored in the non-volatile memory 3.
Store. Further, the CPU 14 selectively discharges at predetermined times.
In the characteristic measurement mode, the rated load 17 is connected to the battery group 2.
Then, the terminal voltage is taken in and the terminal voltage is
Collect terminal voltage data at predetermined intervals until
You. The terminal voltage reaches the specified level, and the discharge characteristic measurement is completed.
Is completed, the battery capacity is calculated based on the terminal voltage data.
Calculate and display, and measure discharge characteristics and battery capacity
The data is stored in the nonvolatile memory 3. In addition, CP
U14 can be selectively measured by user operation such as switch operation.
In the constant mode, connect the rated load 17 to the battery group 2
When the terminal voltage is captured and the terminal voltage is captured,
Immediately disconnect the rated load 17. And non-volatile memory
The data obtained in the previous discharge characteristic measurement stored in 3
Data of the terminal voltage and the actual measurement result
Compared to the terminal voltage of the terminal, the time of approximately the same value is used in total
The remaining time is determined and the remaining usage time or remaining amount is calculated and displayed. Embodiment a, Configuration and Operation of One Embodiment Hereinafter, one embodiment of the present invention will be described with reference to the drawings.
I will tell. FIG. 1 shows a case where the present invention is applied to a charging device.
FIG. 1 shows one embodiment of the present invention.
Is a battery pack, and 7 is a charging device.
It is. The inside of the battery pack 1 is indicated by a broken line 2.
Battery group formed by connecting a plurality of power cells in series
The nonvolatile memory 3 is housed. For example, with batteries
Then, a nickel-cadmium battery is used. + Electrode of battery group 2
Connection terminal 4 derived from and the connection derived from the-electrode
Terminal 5 is located at a predetermined position on the outer surface of the battery pack 1 housing.
Has been established. As the nonvolatile memory 3, for example,
If an EEPROM is used, it is derived from the non-volatile memory 3.
The input / output terminal 6 is at a predetermined position on the outer surface of the housing of the battery pack 1
It is arranged in. The charging device 7 has an automatic measuring means centered on the CPU 14.
It automatically measures the number of charges, discharge characteristics, etc.
It is configured as follows. The A / D converter 13 and the heat
, Cooler 22, switch circuit 15, display unit 19, switch group 23
And each of the interface circuits 18 are connected, and the CPU 14
, An input / output terminal 10 is derived. In addition,
Input / output terminal 20 is led out of the interface circuit 18.
You. Although not shown, the CPU 14 is an R that incorporates control software.
The configuration includes an OM, an input / output device, and the like. The charging device 7 has a storage space for the battery pack 1.
The base 11 is formed. Forming this storage space 11
The terminal 15a of the switch circuit 15 is located at a predetermined position on the outer surface of the housing.
Terminal 8 derived from the terminal and the terminal derived from terminal 15b
The child 9 is arranged and the input / output derived from the CPU 14
A force terminal 10 is provided. With it, storage space
A heater 21 and a cooler 22 are provided on the outer surface of the housing forming 11.
In addition, a temperature sensor 12 is provided. This chick
The heater 21 and the cooler 22 are controlled by the CPU 14 as described later.
Driven by a control signal, the battery pack 2 on the battery pack 1 side
Charging is performed optimally within the temperature range within the specified range.
Is turned on. The charging circuit is connected between the terminals 15c and 15f of the switch circuit 15.
16 is connected, and a rated load 17 is connected between terminals 15e and 15h.
It is connected. Also, the terminal 15d of the switch circuit 15 and the terminal
The child 15g is open. This switch circuit 15
It has a control terminal, and the control terminal
Is supplied, and selectively a predetermined terminal 15a (15b) and a terminal 15c,
15d, 15e (15f, 15g, 15h) is connected. That is, at the time of charging, the terminal 15c is connected to the terminal 15a.
At the same time, the terminal 15f is connected to the terminal 15b. In addition, discharge characteristics
When measuring the performance (or when measuring the remaining amount), connect terminal 1 to terminal 15a.
5e is connected and terminal 15h is connected to terminal 15b.
You. In the case other than the above-described measurement of the charge and discharge characteristics,
The terminal 15a is connected to the terminal 15d, and the terminal 15b is connected to the terminal 15g.
Connected. The A / D converter 13 connected to the CPU 14 has a connection terminal.
8 and the temperature sensor 12 are connected. Because of this, necessary
And the terminal voltage of the battery group 2 via the A / D converter 13 according to
Data such as the ambient temperature is taken into the CPU 14. The CPU 14 controls the operation state of the switch group 23 and the battery pack.
Responds to a signal indicating that
To various modes and perform various processing to control each part.
Control signal and form a display signal as necessary,
A display signal is supplied to 19 to display predetermined information. For example, the battery pack 1 is stored in the storage space 11.
Battery pack as shown by the dashed arrow in the figure.
The connection terminal 4 on the side of the charger 1 and the connection terminal 8 on the side of the charging device 7
Connected to the connection terminal 5 of the battery pack 1 and the charging device
The connection terminal 9 on the side 7 is connected. With it
The input / output terminal 6 on the battery pack 1 side and the charging device 7 side
CPU 14 and non-volatile memory
3 are combined. An external input device is connected to the external input terminal 20 in the state described above.
Then, the non-volatile memory 3 is set in the write state,
Write data from a connected external input device
To the non-volatile memory 3 via the interface circuit 18 and the CPU 14.
It is supplied and stored in a predetermined area. For example, external input
Indicates the administrator name, use start date, ID number, etc. by the device
Data is written. The CPU 14 also allows the battery pack 1 to be used as a storage space.
When it is stored, it is automatically stored in the non-volatile memory 3.
The charge count data is read out and the charge count is displayed on the display unit 19.
indicate. And when it is set to the charge mode selectively
Are the heater 21 and the cooler 22 based on the value of the temperature sensor 12.
Is operated to optimize the ambient temperature of the battery pack 1.
Charge the battery by connecting the charging circuit 16 to the battery group 2 while controlling the battery
I do. The terminal voltage value of the battery group 2 is taken in and monitored,
Charging ends when a voltage drop above a certain level is detected.
The flag indicating the number of times of charging is updated, and the number of times of charging is updated.
Data and the like are stored in the nonvolatile memory 3. Further, the CPU 14 selectively measures the discharge characteristics at predetermined times.
In the mode, the rated load 17 is connected to the battery group 2 and
Input voltage and the terminal voltage drops to a specified level.
Until the data of the terminal voltage is collected at a predetermined cycle. Terminal
When the voltage reaches a predetermined level and the discharge characteristic measurement ends,
Calculates and displays the battery capacity based on the terminal voltage data.
Data and discharge capacity measurement and battery capacity data.
It is stored in the volatile memory 3. Further, the CPU 14 is operated by a user's switch operation or the like.
When the balance mode is selected, the rated load 17 is charged.
Connect to Pond Group 2 to capture terminal voltage, measure terminal voltage
Immediately after the end of the load, the rated load 17 is disconnected. Soshi
And the previous discharge characteristic stored in the non-volatile memory 3.
Read the data obtained by the measurement and read the data of the terminal voltage.
The terminal voltage of the actual measurement result
The value time is determined as the total use time, and the remaining use time or remaining
Calculate and display. By the above-described processing, the nonvolatile memory 3
The data stored in the switch group 23
It is read out by a series of operations and CPU 14
It is taken into PU14. Compatible with various data in CPU14
A display signal is formed, and this display signal is supplied to the display unit 19.
Each information is displayed by a character display or the like. Also,
An external output device such as a printer is connected to the external input terminal 20.
Data, the data stored in the non-volatile memory 3
The data generated by the CPU 14 is read as needed.
And output in hardcopy form. A series of processing, battery capacity displayed as required, charging
Refer to the information such as the number of times and the date
The service life is easily determined by the user,
The battery level is displayed as the process of
Processing is easy. b, Description of charging mode The operation of the above-described embodiment will be described more specifically.
You. FIG. 3 is a flowchart showing a series of processes in the charging mode.
This is a flowchart, which is filled in with reference to this flowchart.
The electric operation will be described in detail. First, the battery pack is stored in the storage space 11 of the charging device 7.
1 is automatically stored in the non-volatile memory 3 when stored.
The charge count flag is read (step 41),
In the CPU 14, a display signal is formed. This display signal
Is supplied to the display unit 19, and the number of times of charging is indicated by a number.
(Step 42). And whether the number of charging times is 2500 or more
Is determined (step 43) and the number of charging times is 2500 or more.
In this case, the display signal is
It is formed in the CPU 14 (step 44). This display 1
The user who has confirmed the blinking display of 9 makes the final decision,
The switch group 23 is operated. If you want to charge more,
The process moves to step 46. When not charging
Ends a series of processes (step 57). If the number of recharges is less than 2500, step automatically
The process proceeds to step 46, where the temperature read through the A / D converter 13 is read.
It is determined whether the value of the degree sensor 12 is, for example, 45 ° C or more.
You. If the value of the temperature sensor 12 is determined to be, for example, 45 ° C or higher,
In this case, a control signal is formed in the CPU 14,
A signal is supplied to the cooler 22 and a reference temperature (for example, 20 ° C.)
The cooler 22 operates so as to achieve the above (step 47). If the value of the temperature sensor 12 is determined to be less than 45 ° C,
It is determined whether the value of the temperature sensor 12 is, for example, 10 ° C or less.
(Step 48). The temperature sensor 12 value is, for example, 10 ° C or less
Is determined, the CPU 14 generates a control signal.
The control signal is supplied to the heater 21 and the reference temperature
(For example, 20 ° C.).
49). If the value of the temperature sensor is determined to be greater than 10 ° C,
A control signal for the switch circuit 15 is formed in the CPU 14,
While the terminals 15a and 15c of the switch circuit 15 are connected,
Terminals 15b and 15f are connected, and the charging operation is started (switch
Step 50). When the charging operation is started, first, a charge is obtained at the connection terminal 8.
The value of the terminal voltage of the battery group 2 is supplied to the CPU 14 via the A / D converter 13.
(Step 51). The terminal voltage of battery pack 2
Monitored to determine if -ΔV is detected
(Step 52). When −ΔV is detected, the terminal voltage is
It is determined whether the value is equal to or more than the reference value (step 53). This
Full charge is ensured by the processing of step 52 and step 53
This completes the charging operation (step 54). In other words, the charging time of a completely discharged battery
The characteristic of the terminal voltage is shown by a solid line 32 in FIG.
Voltage drop during terminal voltage rise,
It has a plurality of peaks until it reaches a state of charge. others
Therefore, the CPU 14 monitors the terminal voltage at predetermined intervals, and
Voltage drop (referred to as -ΔV)
The voltage drop is a predetermined level indicated by a broken line 31 in FIG. 2A.
Only when the voltage drops from the above peak
It is determined that the battery has been fully charged. This is based on the terminal voltage
Stop charging even if a voltage drop occurs during rising
Is a process to make a full charge, and a true voltage drop
Is detected and the charging operation ends. When charging is completed, the charging count flag is updated (scan
Step 55), data on the number of charges and ambient temperature
Supplied to the nonvolatile memory 3 of the battery pack 1 and
Is stored in the area (step 56). For example,
If the 500th charge is performed at an ambient temperature of 28 ° C
Indicates that data indicating (500, 28 ° C) is stored in a predetermined area.
You. Then, the cooler 22 and the heater 21 are turned off (step
57), a series of processing in the charging mode is completed.
You. c, Description of discharge characteristic measurement mode FIG. 4 shows a series of processes in the discharge characteristic measurement mode.
It is a flowchart shown, and refer to this flowchart.
Next, the discharge characteristic measurement operation will be described in detail. When a series of processing in the charging mode is completed,
Updated by the previous charging operation stored in the memory 3
The new charging count flag is read (step 61),
The CPU 14 determines whether the number of charges is a multiple of 50.
(Step 62). If the number of charges is a multiple of 50
The CPU 14 shifts to the discharge characteristic measurement mode.
Is formed, and this display signal is displayed on the display unit 19.
And is displayed in characters (step 6
3). If the number of times of charging is not a multiple of 50,
The charging mode is processed (step 75), and the user determines.
Predetermined processing by switch operation (step 45)
Is terminated. The user who confirms the display on the display unit 19 makes a final decision.
And the switch group 23 is operated. Perform discharge characteristic measurement
If not, the process proceeds to step 65. Discharge characteristics measurement
If the setting is not performed, the charging mode will be
Process (step 75), and the user determines
The predetermined process is completed by the switch operation (step 45).
It is. When the operation of the automatic discharge characteristic measurement is started, first, the CPU 1
At 4, a control signal to the switch circuit 15 is formed,
While the terminals 15a and 15e of the switch circuit 15 are connected,
Terminals 15b and 15h are connected to establish a connection with the rated load.
(Step 65). Next, for example, the battery group 2 obtained at the connection terminal 8 every minute
Is read by the CPU 14 via the A / D converter 13.
At the same time, the temperature sensor value is read via the A / D converter 13.
(Step 66). And the terminal voltage of battery group 2 is
Monitored to determine whether the terminal voltage is below the reference value
(Step 67). Until the terminal voltage reaches the reference value,
Step 66 and Step 67 are repeated, and the terminal voltage
Is less than the reference value, the required discharge characteristic data is obtained.
Then, the process proceeds to step 68. In CPU 14, control signal to switch circuit 15 is formed
When the terminals 15a and 15d of the switch circuit 15 are connected,
In both cases, terminals 15b and 15g are connected, and the rated load is disconnected.
(Step 68). Then, the capacity (AH) is calculated from the read discharge characteristic data.
It is calculated (step 69). For example, flowing to the rated load
Current (A) x time required to reach predetermined terminal voltage
(H) x Battery capacity by coefficient from standard temperature (: K1)
Is calculated. Display signal for displaying the calculated value
Is formed in the CPU 14, and this display signal is displayed on the display unit 19.
Supplied and the battery capacity is indicated by a number (step
70). In addition, it is determined whether the battery capacity is less than 50% of the rated capacity
(Step 71) and the battery capacity is less than 50% of the rated capacity.
In this case, the display signal is
It is formed in the CPU 14 (step 72). In other words, the characteristic curve of the battery terminal voltage with respect to the discharge time
As shown in FIG.
Battery capacity decreases as charging and discharging are repeated.
is there. (Note that the characteristics of the new battery are shown in FIG.
The characteristics of an old battery that has been repeatedly charged and discharged
This is indicated by a solid line 35 in FIG. For this reason, CPU14
The fully charged battery group 2 is discharged at the rated load 17,
The terminal voltage is at a predetermined level indicated by a broken line 33 in FIG. 2B.
Collect terminal voltage data until the voltage drops below
To accurately calculate the battery capacity, it will be 50% or less of the rated capacity
It is determined that the service life has expired, and the user is notified by a display. The user who has confirmed the blinking display of the display unit 19, for example,
Comprehensively referring to the number of times of charging, date of starting use, etc.
After making a final decision, the switch group 23 is operated. pull
When using the battery pack 1 continuously, step 74
Move to the processing of. Stop using battery pack 1,
When discarding, a series of processing ends. If the battery capacity is greater than 50%, it is automatically released.
The electrical characteristics and capacity data are supplied to the non-volatile memory 3,
It is stored in a predetermined area (step 74). For example, rated
1 minute after the load is connected and the discharge starts,
Voltage is detected as 12.5V, and the terminal voltage after 2 minutes is detected as 12.4V
When the terminal voltage is detected as 11.9V after 60 minutes,
(1min → 12.5V, 2min → 12.4V,… 60min → 11.9V,…)
Data indicating the battery capacity.
(1.5AH) is stored in the predetermined area. And discharge characteristics
When the battery pack 1 is measured and the terminal voltage drops
On the other hand, the charging mode is set again (step 75).
The battery is fully charged by charging
A series of processes related to the electric characteristic measurement mode is ended. d, Description of remaining amount mode FIG. 5 shows a series of processes in the remaining amount measurement mode.
It is a flowchart, and refer to this flowchart.
The remaining amount measurement operation will be described in detail. For example, there is a fully charged battery pack 1
If you want to know the remaining amount after using
With the battery pack 1 stored in the storage space
Switch group 23 is operated by the user to selectively measure the remaining amount
Mode. If you select the remaining fuel measurement mode,
In the CPU 14, a control signal to the switch circuit 15 is formed.
When the terminals 15a and 15e of the switch circuit 15 are connected,
Are connected to the terminals 15b and 15h, and the rated load 17 (or
(Actual load with a clear capacity). Then connect
The terminal voltage of the battery group 2 obtained at the terminal 8 operates the A / D converter 13
Is read by the CPU 14 via the
It is read via the / D converter 13. And the terminal voltage and
As soon as the values of the temperature and temperature sensors are read into the CPU 14,
Terminals 15a and 15d of the switch circuit 15 are connected, and
15b and 15g are connected and rated load 17 (or capacity
The reliable actual load is separated (step 81). Get the data needed to calculate the battery level
Is stored in the nonvolatile memory 3 of the battery pack 1
Discharge characteristics obtained in the previous discharge characteristic measurement mode
The property and capacity data are read (step 82). Then, the temperature value from the standard temperature is added to the actual terminal voltage value.
Number (: K1) and, if necessary, the difference between the actual load and the rated load 17
Multiplied by a correction coefficient such as the coefficient (: R1)
Is done. The obtained correction value is stored in the nonvolatile memory 3.
Terminal voltage data obtained from the previous discharge characteristic measurement
And determine the time of approximately equal value as the total usage time
You. And further, the battery obtained in the previous discharge characteristic measurement
Total usage (AH) obtained from total usage time from capacity (AH)
Is subtracted, and the remaining battery level is calculated (step 83). A display signal for displaying the calculated value is sent to the CPU 14.
The display signal is supplied to the display unit 19,
The remaining amount of the pond or the remaining usage time obtained from the remaining amount
Is displayed, and a series of processing is completed (step 84).
You. One embodiment in which the present invention is applied to a charging device
As described above, the present invention is applicable to a device driven by a battery.
May be used. In this case, it is driven by a battery.
When a battery is stored in the storage space of the
The actual load on the drive unit is changed to the quantity measurement mode.
Multiplied by the coefficient (: R1) of the difference from the rated load
The amount may be calculated and displayed on the drive device side. In one embodiment of the present invention, the charging device 7 side
Although the configuration in which the display unit 19 is provided has been described,
A display unit may be provided to display the remaining amount. [Effects of the Invention] In the present invention, when a nonvolatile memory is provided on the battery side,
In addition, the device with storage space
Dynamic measurement means and the like are provided. Battery is stored in storage space
If this is done, the number of times of charge and discharge characteristics are automatically measured.
The battery capacity is calculated based on those data.
Displayed, and discharge characteristics and capacity data are displayed on the battery side.
Is stored in a non-volatile memory. Also, if necessary,
When the mode is set to the quantity measurement mode, the terminal voltage of the battery is measured,
The measurement result and the previous value stored in the non-volatile memory
Data such as discharge characteristics and capacity obtained by discharge characteristics measurement
The remaining amount is calculated based on the data and displayed. Also this
Are stored in non-volatile memory intensively by various processes
Various data can be easily read and displayed as needed.
You. Therefore, according to the present invention, the discharge characteristics automatically performed are set.
Accurate battery capacity based on data obtained from battery performance measurements
Is calculated and the value of the capacity is displayed.
The user must be able to reliably and accurately determine the battery capacity.
it can. For this reason, it is easy to predict the battery life.
Can use the battery economically and efficiently
You. Further, according to the present invention, a battery that is being used can be used.
The remaining time is accurately calculated and the value of the remaining time is displayed.
Therefore, users can easily and accurately know the remaining battery level.
Battery management can be performed easily. Further, according to the present invention, the nonvolatile memory provided on the battery side
Data about each battery is stored separately in the memory.
Data can be easily read and displayed.
Battery history management.
You. Incidentally, in one embodiment of the present invention, the circumference is set to an optimum state.
Charging is performed by controlling the ambient temperature and the terminal voltage of the battery is controlled.
Takes in the value and monitors it to determine the voltage drop above a certain level.
Operate so that charging ends only when detected
Therefore, full charging can be performed more accurately. Ma
In one embodiment of the present invention, the battery is fully charged.
Connect the rated load to the battery and take in the terminal voltage
And discharge characteristics data until the terminal voltage reaches the specified level.
Accurately calculates the battery capacity based on the
Information that is reliable in determining the lifespan
Can be provided. Further, in one embodiment of the present invention,
Accurate non-volatile memory with accurate discharge characteristics and capacity data.
Actual end obtained by the same measuring means, stored in the memory
Since the remaining power is calculated based on the slave voltage data,
The battery level can be calculated in
Effective and highly reliable information can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of one embodiment of the present invention, FIG. 2 is a characteristic diagram used to explain the operation of one embodiment of the present invention, and FIG. FIG. 4 is a flowchart for explaining a discharge characteristic measuring mode in one embodiment of the present invention, and FIG. 5 is a flowchart for explaining a remaining amount measuring mode in one embodiment of the present invention. is there. Description of main reference numerals in the drawings 1: battery pack, 2: battery group, 3: non-volatile memory, 7: charging device, 12: temperature sensor, 13: A / D converter, 14: CPU, 15: switch circuit, 16: charging circuit, 17: rated load, 18: interface circuit, 19: display, 21: heater, 22: cooler.

Claims (1)

(57) [Claims] In a device having a space for storing a rechargeable battery with a built-in nonvolatile memory, a predetermined load was connected for a predetermined time, a terminal voltage of the battery was measured, and after the measurement, the load was disconnected from the battery and measured. The obtained discharge characteristic data and capacity data of the battery are written in the nonvolatile memory, and the total use time or the total use amount is calculated from the discharge characteristic data read from the nonvolatile memory and the terminal voltage of the battery. Subtracting the total usage time or total usage from the capacity data read by the non-volatile memory to calculate the remaining usage time or remaining amount of the battery, and storing the remaining usage time in a device in which the battery is stored. A device having a space for storing a rechargeable battery with a built-in nonvolatile memory, characterized by having a means for displaying a remaining amount. 2. In a device having a space for storing a rechargeable battery provided with a nonvolatile memory and a display means, a predetermined load is connected for a predetermined time, a terminal voltage of the battery is measured, and after the measurement, the load is disconnected from the battery. Writing the discharge characteristic data and capacity data of the battery obtained as a result of the measurement into the nonvolatile memory, and calculating the total use time or total use amount from the discharge characteristic data read from the nonvolatile memory and the terminal voltage of the battery. Is calculated, and the total use time or total use amount is subtracted from the capacity data read by the nonvolatile memory to calculate the remaining use time or remaining amount of the battery, and the remaining use time is displayed on the battery display means. A non-volatile memory having means for displaying time or remaining amount, and a storage for storing a rechargeable battery provided with a display means. Device having an over nest.