JP2809661B2 - Battery driven information processing device, battery power supply system, and battery management device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery-powered information processing apparatus, a battery power supply system suitable for driving an information processing apparatus and other electronic devices, and a battery management apparatus. A rechargeable battery having a discharge characteristic that causes a sharp voltage drop at the end of its life,
For example, the present invention relates to an information processing device that operates using a nickel cadmium battery as a power source, a battery power supply system, and a battery management device.

[Prior art] In a handy type word processor using a nickel cadmium battery as a power source and a desktop computer,
At the end of the discharge life of a nickel cadmium battery, the battery voltage may drop sharply and cause a malfunction. In particular, when a printer or a floppy disk drive that consumes a large amount of power is being driven, the terminal voltage drops sharply.

Heretofore, it has been proposed that a battery-driven device of this type detects a battery voltage falling below a specified voltage and warns a user by detecting this (for example, Japanese Patent Application Laid-Open No. -151908, JP-A-62-251912, JP-A-62-25
1913 publication etc.).

[Problems to be Solved by the Invention] As shown in FIG. 3, the discharge characteristics of a nickel cadmium battery are different from the discharge characteristics of a dry battery, and the terminal voltage Vb on the vertical axis is almost equal to the discharge time on the horizontal axis t. It is constant. For this reason, it was difficult to predict the discharge life of the battery based on the terminal voltage. In addition, since the terminal voltage change occurs at the end of the battery discharge life, when a printer or a floppy disk drive that consumes a large amount of current is driven at the end of the battery discharge life, the terminal voltage drops particularly sharply. During printing by the printer or during access to the floppy disk device, the voltage may drop below the specified voltage and cause a malfunction.

On the other hand, Japanese Patent Application Laid-Open No. 63-101785 proposes a battery remaining capacity display device used for equipment using a battery, particularly for audio equipment using a rechargeable battery.

The battery remaining capacity display device includes an oscillation circuit, a counting circuit that divides and counts the output of the oscillation circuit, a display circuit that displays the output of the counting circuit, and a battery. In accordance with the discharge current and the self-discharge current, the oscillation frequency of the oscillation circuit or the division ratio of the counting circuit is determined. It is characterized in that the remaining capacity of the battery is indicated by displaying on a display circuit.

However, in this conventional device, the remaining capacity is obtained by increasing or decreasing the count value of the counting circuit in proportion to the time during which the charging current and the discharging current flow. Based on the remaining capacity, the remaining capacity is calculated. Therefore, when a device is used at a certain remaining capacity, there is a problem that whether or not the device can be used cannot be known in advance.

Such prediction of the remaining capacity for future use is extremely important, for example, in an information processing apparatus such as a battery-driven word processor, in order to prevent a shortage of capacity in the middle of processing and prevent execution of the processing. It is.

However, as described above, in the related art, such a management of the remaining capacity is not considered in a battery that supplies power to a general load or a battery that is a power source of an information processing apparatus. I didn't.

Therefore, an object of the present invention is to predictably manage the capacity of a battery such as a nickel cadmium battery in which a change in terminal voltage occurs at the end of the battery's discharge life,
An object of the present invention is to provide a battery-driven information processing device, a battery power supply system, and a battery management device.

[Means for Solving the Problems] As means for solving the problems, the present application provides the following inventions.

A first invention, as shown in FIG. 1A, includes an information processing apparatus including a rechargeable battery serving as a power source of hardware constituting a system for performing information processing, and a charging unit for charging the battery. A battery management unit that predicts and manages the capacity of the battery, the battery management unit detects the presence or absence of charging, determines a charging time, and increases the battery capacity by charging from the charging time and the charging current. Charging capacity calculating means for calculating the minute (charging capacity); consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery from an average used current and a usage time required for executing a process instructed in the system; It is characterized by comprising a remaining capacity calculating means for calculating the remaining capacity of the battery from the charged capacity and the consumed capacity.

As shown in FIG. 1B, a second invention is an information processing apparatus including a rechargeable battery serving as a power source of hardware constituting a system for performing information processing, and a charging unit for charging the battery. A battery management unit that predicts and manages the capacity of the battery, the battery management unit detects the presence or absence of charging, determines a charging time, and increases the battery capacity by charging from the charging time and the charging current. Charge capacity calculating means for calculating the minutes, consumed capacity calculating means for calculating the estimated consumed capacity supplied by the battery from the average used current and the used time required to execute the processing instructed in the system, and the battery by the charging Comparing the increased capacity with the predicted consumed capacity to determine whether or not the process can be executed, and outputting the result of the determination;

A third invention is configured to include a rechargeable battery connected to a load and serving as a power source thereof, a charging unit for charging the battery, and a battery management unit for predicting and managing the capacity of the battery. A battery power supply system, wherein the battery management unit detects the presence or absence of charging, determines a charging time, and calculates an increase in battery capacity due to charging from the charging time and the charging current; A consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery from the average use current and the use time of the load; and a decrease in the remaining capacity of the battery from the increase in the battery capacity due to the charge and the predicted consumption capacity. And a remaining capacity calculating means for calculating the remaining capacity.

A fourth invention is configured to include a rechargeable battery connected to a load and serving as a power source thereof, a charging unit for charging the battery, and a battery management unit for predicting and managing the capacity of the battery. A battery power supply system, wherein the battery management unit detects the presence or absence of charging, determines a charging time, and calculates, from the charging time and the charging current, an increase in battery capacity due to charging; A consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery from the average usage current and usage time of the load; comparing the increase in the battery capacity due to the charging with the predicted consumption capacity, It is characterized in that it is configured to determine whether or not the operation is executable, and to include an execution determination unit that outputs the determination result.

A fifth invention is a battery management device that is capable of charging and predicts and manages the capacity of a battery connected to a load and serving as an electric power source. From the time and the charging current, a charging capacity calculating means for calculating an increase in battery capacity due to charging, and a consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery from the average use current and use time of the load. And a remaining capacity calculating means for calculating a decrease in the remaining capacity of the battery from the increase in the battery capacity due to the charging and the predicted consumption capacity.

A sixth aspect of the present invention is a battery management device that is capable of charging and predicts and manages the capacity of a battery connected to a load and serving as a power source thereof. From the time and the charging current, a charging capacity calculating means for calculating an increase in battery capacity due to charging, and a consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery from the average use current and use time of the load. An execution feasibility determining unit configured to determine whether the operation of the load is feasible by comparing the increase in the battery capacity due to the charging with the predicted consumption capacity, and to output the determination result. It is characterized by being performed.

The present application also provides an invention having the following preferred embodiments in addition to the above-mentioned nuclear invention.

First, regarding the second, fourth and sixth inventions,
When the determination result of the execution availability determination unit is not executable, the required charging time calculation unit that calculates the time required for the increase in the battery capacity due to the charging to exceed the predicted consumption capacity and outputs the calculation result is provided. Each of the inventions additionally configured is provided.

Next, for each of the first to sixth inventions and the inventions to which the above-mentioned preferred embodiments are added, the following a
An invention is provided which includes one or more of the respective constituent elements of (1) to (1).

a. Saturation charge time calculation means for calculating a charge time until reaching the saturation charge capacity and outputting the calculation result.

b.In the case where the charging current can be switched, comparing the preset saturation charging capacity of the battery with the increase in the battery capacity due to the calculated charging, and when the latter is large, the charging current is reduced to a very small current. Charge current switching means for switching.

c. In the case where the charging current can be switched, a preset saturated charging capacity of the battery is compared with an increase in the battery capacity due to the calculated charging. Thereafter, charging current switching means for switching the charging current to a very small current.

d. Voltage drop detection means for detecting a drop in battery terminal voltage in a voltage range higher than the operation limit voltage, and converting the operable time from the detection point to the operation limit voltage corresponding to the load, and performing the conversion. Operation time conversion means for outputting the result.

e. In a voltage range higher than the operation limit voltage, a voltage drop detecting means for detecting a terminal voltage drop of the battery, and, when the terminal voltage drop of the battery is detected, the remaining capacity of the battery set in advance is charged. Charge capacity setting means for changing and setting the remaining capacity as capacity calculation means.

f. Display means for displaying the judgment result of the execution possibility judgment means.

g. Display means for displaying the calculation result of the required charging time calculation means.

h. Display means for displaying the calculation result of the saturation charge time calculation means.

i. Display means for displaying the conversion result of the operable time conversion means.

j. Display means for displaying the remaining capacity calculated by the remaining capacity calculation means.

k. Display means for displaying an increase in battery capacity due to charging calculated by the charging capacity calculation means.

l. Means for displaying the predicted consumed capacity calculated by the consumed capacity calculating means.

In each of the inventions related to the information processing apparatus provided by the present application, the battery management unit can be configured by hardware configuring a system that performs information processing. For example, the battery management unit uses a central processing unit, which is a component of hardware configuring a system for performing information processing, a program memory that stores a data processing program executed by the central processing unit, and a work memory. Can be configured.

Similarly, the invention relating to the battery management unit and the battery management device of the battery power supply system is also performed using the central processing unit, the program memory storing the data processing program executed by the central processing unit, and the work memory. can do.

In addition, the determination result output in each of the above-described inventions,
The output of the calculation result, the conversion result, and the like can be sent to a display device, an audio output device, a numeral (character) display, a display lamp, an alarm, a printer, or the like, and used to notify an external user. Accordingly, each invention of the present application preferably includes such a display device. However, these are
A device connected to the information processing device can be used as appropriate. Further, a dedicated device may be provided.

It is also preferable that the remaining capacity, the increase in the battery capacity due to charging, the estimated consumption capacity, and the like can be similarly displayed externally.

That is, the above-described display means can be configured by providing a display device, a numeral (character) display device, a display lamp, and the like on a battery management unit or a battery management device provided with the display device. Further, if a main unit such as an information processing device to which it is connected has these functions, it may be configured by using them.

The invention of the information processing device provided by the present application is, specifically,
For example, the following mode can be adopted.

That is, the information processing device includes a central processing unit, a program memory and a work memory for storing a data processing program executed by the central processing unit,
A keyboard for inputting data, operation commands, etc. from outside,
A display device, peripheral devices connected as necessary, a power supply device for supplying power thereto, a rechargeable battery serving as a power source of the power supply device, a charging unit for charging the battery, And a battery management unit for predicting and managing the capacity.

Examples of the peripheral device include a floppy disk drive device and a printer.

A rechargeable battery, that is, a storage battery is used as the battery. Such a battery is, for example, a nickel cadmium battery. The charging section for charging the battery preferably has a configuration in which the charging current can be switched between normal charging and minute charging.

In this information processing apparatus, a central processing unit executes a data processing mode, a peripheral device access processing mode, and the like according to a processing program stored in a program memory in response to an input from the keyboard. In performing these operations, power is supplied from the battery, but the battery may be in a charged state or in a non-charged state.

The battery management unit, which is a component of the information processing apparatus, includes, for example, a charge detection unit for the battery, and a time detection unit that detects time of charging of the charge detection unit. A charging capacity calculating means for calculating an increase in battery capacity due to charging based on the charging time detected by the unit; and a consumption capacity reference value required to execute the processing mode stored in correspondence with each processing mode. A consumption that has a reference capacity setting unit and calculates the total consumption capacity (predicted consumption capacity) whose consumption in the processing mode is predicted from the consumption capacity reference value set in the reference capacity setting unit corresponding to the commanded processing mode. Capacity calculating means; comparing the amount of increase in battery capacity due to charging obtained from the charging capacity calculating means and the consumed capacity calculating means with the predicted consumed capacity to determine whether the commanded processing mode can be executed. The determination unit outputs the determination result to a display unit to display the determination result. If the determination unit determines that the execution of the command processing mode is impossible, it is obtained from the charge capacity calculation unit. A required charging time calculating means for calculating a charging time required for the value to exceed the total consumed capacity (predicted consumed capacity) for which consumption in the command processing mode is predicted, and outputting the calculated result to a display means for display; Are provided.

With the configuration as described above, the present invention predicts the remaining capacity of the battery. By comparing the remaining capacity with the saturated capacity reference value, it is possible to display the required charging time up to the saturated charging and determine the timing of switching to the minute charging after the saturated charging by calculation. At this time, the normal charging is performed for a certain time. Thus, the error accumulation can be corrected by the calculation means.

In addition, the operable time up to the operation limit voltage is calculated by comparing the remaining capacity reference value at the time when the terminal voltage of the battery decreases and the remaining capacity of the storage battery, and the operable time can be displayed. At this point, by changing the remaining capacity of the storage battery to the remaining capacity reference value, the error accumulation can be corrected by the calculating means.

Note that the information processing apparatus of the present invention can be applied to, for example, a document editing processing apparatus, a personal computer, and the like. In particular, it is suitable for small devices such as a laptop type and a handheld type.

Further, the battery power supply system of the present invention can be applied not only to the information processing apparatus but also to a power supply apparatus of another electronic device. For example, the present invention can be applied to a power supply device of a peripheral device, a power supply device of a communication device, and the like.

Furthermore, since the battery management device of the present invention can be constituted by a microcomputer, it can be formed as an IC. Therefore, the battery management unit of the information processing apparatus and the battery management unit of the battery power supply system can be mounted.

[Operation] In the present invention, the remaining capacity of the battery is calculated from the increase in the battery capacity due to charging and the predicted consumption capacity.

The increase in battery capacity due to charging of the battery is calculated as: increase in battery capacity due to charging = charging current x charging time. The predicted consumption capacity consumed from the battery is calculated as: predicted consumption capacity = average current consumption x usage time. Therefore, the amount of decrease in the remaining capacity of the battery is calculated as: decrease in remaining capacity = increase in battery capacity due to charging−estimated consumed capacity.

The remaining capacity of the battery is predicted based on the capacities obtained from the charging capacity calculating means and the consumed capacity calculating means.

By comparing the remaining capacity with the saturated capacity reference value, it is possible to display the required charging time until the saturated charge and determine the timing of switching to the minute charge after the saturated charge by calculation. At this point, by performing normal charging for a certain period of time, it becomes possible to correct the error accumulation by the calculation means. Further, by comparing the remaining capacity reference value at the time when the terminal voltage of the battery is lowered with the remaining capacity of the battery, the operable time up to the operation limit voltage is calculated, and the operable time can be displayed. At this point, by changing the remaining capacity of the battery to the remaining capacity reference value, the error accumulation can be corrected by the calculating means.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing the overall configuration of a document editing processing apparatus according to one embodiment of the present invention.

An AC adapter 1 for rectifying and smoothing a commercial power supply and converting the commercial power into DC power;
A charging circuit 2 having a constant current circuit capable of switching a current value for charging the battery 3 with DC power, a power supply 4 for converting the power of the battery 3 into stabilized DC power, and turning on a document editing processor. Switch 30 for turning on / off, display 9,
Printer 6, floppy disk device (hereinafter referred to as FDD)
The main control circuit 5 controls the keyboard 7 and the keyboard 10 and executes a document editing process.

FIG. 2 is a block diagram showing the main control circuit 5 in detail.

The main control circuit 5 has a document editing processing unit used to execute the document editing process, and a battery management unit that manages the remaining capacity of the battery. Both of them include a central processing unit (hereinafter, referred to as a CPU) 22 as a component.
The CPU 22 is connected to each component described below via a bus line 21 and controls the components.

The document editing processing unit includes the CPU 22 and the CPU 22 after power-on.
A program memory 14 that stores a program for executing a function as a document editing processing device, a work memory 15 that the CPU 22 uses for document editing processing and other processing operations,
A character generator 16 that stores display characters as dot data, a display controller 19 that controls the display state of the display 9, a printer controller 17 that controls the printer 6 to perform printing, and exchanges information with the FDD 7. Floppy disk controller (hereinafter FD)
C) 18 and a keyboard 1 for inputting information from outside
0, a backup memory 24 backed up by a battery 25, and a backup memory control circuit 26 for controlling the same.

The battery management unit, the CPU 22, the aging circuit A92 which is backed up by the battery 27 and stores the idle time when the power switch 30 is off, and the aging circuit B91 which stores the charging time,
Charge detection unit 23 that detects the state of charge when switch 30 is on
And a terminal voltage detection circuit 122 that is backed up by the battery 123, can detect a drop in the terminal voltage of the battery 3, and can further retain detection information of the voltage drop, and a charging current control that controls a charging current value of the charging circuit 2. And a signal 120.

The document editing apparatus according to the present embodiment includes a battery 3 serving as a power source.
A nickel cadmium battery is used. This nickel cadmium battery has discharge characteristics as shown in FIG.

In FIG. 3, the vertical axis represents the terminal voltage Vb of the battery 3, and the horizontal axis represents the discharge time t. As is clear from the discharge characteristics in the figure, the nickel cadmium battery is
The terminal voltage change is small, and the terminal voltage changes rapidly at the end of the battery discharge life.

The terminal voltage drop detection circuit 122 converts the detection voltage Vd value into
As shown in FIG. 3, the voltage is set to be equal to or higher than the operation limit voltage of the power supply device 4. Thereby, the crisis state of the battery 3 can be detected in advance.

Next, the CPU 22 in the document editing processing apparatus as described above
FIG. 4 shows an outline of a data processing program according to the present invention.

In the document editing process 32 of the document editing process program 31, a process of inputting key data from the keyboard 10, a document editing process, and a display process are executed.

The command mode execution availability determination process 33 is a process in which the processing mode designated by the keyboard 10 corresponds to either the print processing mode for driving the printer 6 or the FDD access processing mode for accessing the FDD 7 in the execution process of the document editing process 32. Then, it is determined whether or not the remaining capacity of the battery 3 at this time is sufficient to execute the printer control processing 35 or the FDD access processing 34. If the remaining capacity is sufficient, the printer control processing 35 or the FDD access processing 34 is executed.

Next, the remaining capacity of the battery 3 is predicted, and the printer control processing is performed.
The determination of whether or not the FDD access process 34 can be executed will be described.

FIG. 5 shows a program executed by the main control circuit 5 centering on the CPU 22 for the processing from switch-on to switch-off. Here, the CPU 22 executes functions such as charging capacity setting means and charging capacity calculating means.

First, when charging is performed in the initial state where the battery 3 is not charged, the terminal voltage of the battery 3 sharply rises, and when the voltage exceeds the operation limit voltage, the power supply device starts operating. Is executed.

The processing program performs voltage detection by the terminal voltage drop detection circuit 122 in processing steps 130 and 131, and
A determination is made as to whether the terminal voltage has risen to a stable voltage and has exceeded the detection voltage Vd value.

In the processing step 132, it is determined whether or not the terminal voltage of the battery 3 has dropped below the detection voltage Vd before the switch-on. If so, in process step 133,
Referring to the remaining capacity of the battery 3 at the time of the detection voltage Vd value from the program memory 14, the total charge capacity of the backup memory is changed to the remaining capacity in the processing step 134. In processing step 135, the detection information of the terminal voltage drop detection circuit 122 is reset, and in processing step 136, the time information of the aging circuit A92 and the aging circuit B91 is reset.

Next, in processing steps 52, 53, and 54, a timer inside the CPU 22 is initialized. By this initialization, CPU2
2 executes a timer interrupt program 61 of a fixed period.

Processing steps 55, 56, 57 and 58 are performed when the switch 30 is off.
In other words, the idle time and charging time in the unused state are detected,
This is a program that calculates an increase in battery capacity due to charging and stores it in a memory.

First, in processing step 55, the standing time detected by the aging circuit A92 backed up by the battery 27 and the aging circuit B
91 refers to the detected charging time. Next, in processing step 56, for the charging time, the amount of increase in battery capacity due to charging = constant current value × charging time, based on the constant current value of charging circuit 2. Also, with respect to the leaving time, the discharge capacity of spontaneous discharge due to the internal impedance = discharge current per unit time × leaving time can be calculated. In other words, the increase in battery capacity due to charging in consideration of spontaneous discharge is the increase in battery capacity due to charging in consideration of spontaneous discharge = (constant current value x charging time)-(discharge current per unit time x idle time). Become.

In the processing step 57, the increase in the battery capacity due to charging is stored in the backup memory 24, and the total charging capacity is updated. In the processing step 58, the time information of the aging circuit A92 and the aging circuit B91 is reset, and the process proceeds to the document editing processing program of the processing step 31.

If the terminal voltage of the battery 3 drops due to non-charging during the execution of the document editing processing program, or if an error is accumulated during calculation of the total charge capacity and the actual remaining capacity is lower than the calculated total charge capacity, the command mode is executed. Is executed, the terminal voltage of the battery 3 decreases. When the terminal voltage drops below the detection voltage Vd value of the terminal voltage drop detection circuit 122, the processing shifts to a terminal voltage drop processing program of processing step 137.

Next, referring to FIG.
7 is explained. Here, the CPU 22 mainly executes functions such as a charging capacity setting unit and an operable time conversion unit.

Processing steps 160 and 161 detect the terminal voltage drop and confirm the terminal voltage drop. If the voltage is low, first
In processing step 163, execution of the command mode is stopped to suppress a sharp voltage drop.

Next, in processing step 164, the remaining capacity of the battery 3 at the time of the detected voltage Vd value is referred from the program memory 14, and in processing step 165, the total charging capacity of the backup memory 24 is changed to the referred remaining capacity.

In processing step 166, referring to the operation time from the program memory 14 to the operation limit voltage, the processing step 167
Displays the operable time. The processing step 169 determines whether the AC adapter 1 is connected and charging has been performed, and if the charging has not been performed, the operable time is recalculated in the processing step 168. The display of the operable time is performed until charging is performed, and the user is in a crisis state.

FIG. 6 shows an integration process of the charged capacity executed by the timer interruption program 61 of the document editing process program 31. That is, here, the CPU 22 executes functions such as a consumed capacity calculating means, a charged capacity calculating means, a remaining capacity calculating means, and a charging current switching means.

First, in processing step 100, the power consumption of the power supply device 4 and the main control circuit 5, which are loads of the battery 3, is referred to from the program memory 14, and in processing step 101, the converted consumption capacity = Convert to the amount corresponding to the consumed capacity as current consumption x interrupt time interval.

In processing steps 62 and 63, the state of charge of the charging circuit 2 is detected, and it is determined whether or not charging is in progress.

If the battery is being charged, the total charge capacity stored in the backup memory 24 is referred to in a processing step 64. In the processing step 65, the saturated charge capacity of the battery is referred from the program memory 14. In processing step 66, the current total charge capacity and the saturation charge capacity are compared.

If the total charge capacity value ≦ saturated charge capacity value, in process step 150, the charge current is set to the normal charge current, and the process proceeds to process step 67.

In the processing step 67, based on the time interval of the timer interruption, the converted charge capacity is converted into an amount corresponding to the increase in the battery capacity due to charging, as follows: conversion capacity = constant current value of charging circuit 2 × interruption time interval.

Next, in processing step 68, the total charging capacity of the backup memory 24 + the converted charging capacity of the processing step 67−the converted consumption capacity of the processing step 101 is calculated.
Update 24 total charging capacities.

On the other hand, if the charging is not performed by the AC adapter 1 in the processing step 63, the processing step 102 proceeds to a processing step
Calculate the converted consumption capacity of 101. Again, step 6
At 9, the total charge capacity of the backup memory 24 is updated.

Next, a processing step 154 calculates a saturation capacity-a total charging capacity of the backup memory 24, and in a processing step 155, calculates a charging time required to reach the saturation capacity by a required charging time = (saturation capacity-total charging capacity) / charging. Calculate as the constant current value of circuit 2 and display the required charging time.

If the battery 3 has reached the saturation capacity in the processing step 66, the processing step 151 is executed. Processing Step 15
Reference numerals 1 and 152 denote processing for correcting error accumulation due to long-term use.

When the correction is selected in the processing step 151, the normal charging is performed for an arbitrary time in the processing step 152. By this processing, even when the total charge capacity calculated by the backup memory 24 does not reach the actual saturation capacity, the saturation capacity can be forcibly set, and the calculation error can be corrected. After the correction, in the processing step 153, the charging is switched to the minute charging.

As described above, the total charge capacity value of the backup memory 24 is constantly updated to the latest remaining capacity value.

Next, referring to FIG. 7, a description will be given of a command mode execution availability determination process 33 for executing the print processing mode and / or the FDD access processing mode. The CPU 22 executes functions such as a consumed capacity calculating unit, a charging current switching unit, a charged capacity calculating unit, an execution determination unit, a required charging time calculating unit, a remaining capacity calculating unit, and a saturated charging time calculating unit.

Print processing mode from the keyboard 10 and / or
When the FDD access processing mode is designated, first, in a processing step 72, the total charging capacity of the backup memory 24 is referred to. Next, the consumed capacity in the processing mode specified by the processing steps 73 and 74 is calculated.

For example, in the case of the print processing mode, it can be calculated by the following formula: consumption capacity = (average current consumption of a driving system such as a motor × printing time) + (average consumption capacity per character × number of printed characters) The print time can be calculated based on the number of print lines and the state of the character arrangement of one line.

In the FDD access processing mode, it can be calculated by the following formula: consumption capacity = (average current consumption of drive system such as motor) x (access time). The access time includes the initial time of the FDD 7 and the transfer data access time, and is the entire time for driving the motor and the like.

For the processing mode specified in the processing step 73, the average current consumption of the drive system such as a motor, which is a reference value, and the average consumption capacity per character are read from the program memory 14 in the processing mode specified in the processing step 73. Calculate the capacity consumed by executing the specified processing mode.

A processing step 75 compares the consumed capacity by executing the command mode with the total charged capacity.

If the consumption capacity by the execution of the command mode ≦ the total charge capacity, in the processing step 110, the small charge is switched to the normal charge, and the command mode of the processing step 77 is executed.

Processing step 11 determines whether or not the command mode execution is an execution during charging. If the battery is being charged, the processing time of the command mode execution is calculated in processing step 112, and in processing step 113, the increase in the battery capacity due to charging within the time of execution of the command mode is calculated by: It is calculated as command mode execution time × constant current value of charging circuit 2. In the processing step 114, an increase in the battery capacity due to the charging in the processing step 113−the consumed capacity in the processing step 74 is calculated. If the calculation result is positive, the battery 3 is charged, and if the calculation result is negative, the battery 3 is discharged.

Next, in a processing step 115, the total charge capacity of the backup memory 24-calculation result of the processing step 114 is calculated.
Change the total charge capacity of 24.

On the other hand, if it is determined in the processing step 111 that charging is not being performed, in a processing step 78, the remaining capacity after execution of the command mode is calculated as remaining capacity = total charge capacity−consumption capacity by execution of the command mode. Then, as in the previous case,
At 79, the total charge capacity of the backup memory 24 is changed.

In processing step 116, the saturation capacity−the total charge capacity of the backup memory 24 is calculated. In processing step 117, the required charging time up to the saturated capacity is calculated as required charging time = (saturated capacity−total charging capacity) / constant current value of charging circuit 2. In step 81, the required charging time is displayed.

On the other hand, in the processing step 75, if the consumption capacity by the execution of the command mode ≧ the total charge capacity, the processing step 76 determines that the charging capacity necessary for the execution of the command mode is the charging capacity required for the execution of the command mode = the consumption by the execution of the command mode. Capacity-Calculated as the total charge capacity of the backup memory 24. In processing step 80, the charging time required for command mode execution is calculated as: charging time required for command mode execution = charge capacity required for command mode execution / constant current value of charging circuit 2; The charge time until the mode can be executed is displayed on the display 9.

According to the embodiment described above, it is possible to store how much remaining capacity of a nickel-cadmium battery currently used in a handy type document editing apparatus has reached. On the other hand, it is possible to calculate the total consumed capacity required to execute each processing mode instructed from the keyboard and determine whether the remaining capacity is sufficient for the total consumed capacity. As a result, if the remaining capacity is sufficient, the processing mode is executed. If the remaining capacity is insufficient, the charging time until the execution of the command mode is displayed. It is possible to notify the remaining capacity.

Further, in the present embodiment, it is possible to display the required charging time up to the saturation capacity of the battery and to inform the remaining capacity of the battery. In addition, when the terminal voltage decreases, the operable time of the apparatus is displayed to improve the usability for the user. Further, according to the present embodiment, the correction of the error accumulation by the calculation of the remaining capacity can be performed when the terminal voltage of the battery decreases and when the charged saturation capacity is reached. Further, overcharging in the saturated charging state is prevented, and the reliability of the device is improved.

Next, another embodiment of the present invention will be described with reference to the drawings.

FIG. 9 is an overall block diagram showing a state in which the battery power supply system according to one embodiment of the present invention is connected to a document editing processing device.

The battery power supply system 201 converts the DC power of the AC adapter 1 that rectifies, smoothes, and converts the commercial power into DC power.
The configuration is such that the battery 3 of the system 201 is charged and power is supplied to the document editing processing device 170 via the switch 30 for turning on / off.

The document editing processing device 170 includes a power supply device 171 that converts the power of the battery 3 into stabilized DC power, and a main control device 172 that controls a peripheral device 173.

The battery power supply system 201 includes a charging circuit 2 including a constant current circuit capable of switching a current value, a rechargeable battery 3,
Regulator 17 to supply power for this system
5 and a portion functioning as the charge capacity calculation device 180.

The part that functions as the charge capacity calculation device 180 is a CPU
176 and other elements. The other elements are backed up by a program memory 182 for executing the function as the charge capacity calculation device 180, a work memory 189, a charge detection unit 178 for detecting the state of charge, and a battery 184, and the terminal voltage of the battery 3 Terminal voltage drop detection circuit 185 that can detect the voltage drop and can further retain the voltage drop detection information.
And a current transformer 174 for detecting a load current of the battery power supply system 201, a current consumption detecting circuit 186 for converting a detected voltage of the current transformer 174 into a detected current, and data exchange with a main controller 172 of the document editing processor 170. And a bus connection circuit 187 that performs the operation. These are the bus lines 200
Is controlled by the CPU 176 via the. Charge capacity calculator 18
The power of 0 is converted into stabilized DC power by the regulator 175 and supplied.

FIG. 10 shows a data processing program by the CPU 176 in the battery power supply system 201 as described above. CPU176
It performs functions such as charging capacity setting means.

In the initial state where the battery 3 is not charged, when the AC adapter 1 is connected and charging is performed, the terminal voltage of the battery 3 sharply increases. When this terminal voltage exceeds the operation limit voltage of the regulator 175 and becomes equal to or higher than the internal reset release voltage of the CPU 176, the processing program is executed.

In this processing program, in processing steps 221 and 222, the voltage of the terminal voltage drop detection circuit 185 is detected, and it is determined whether or not the terminal voltage of the battery 3 has increased to a stable voltage and has exceeded the detection voltage Vd value. I do.

The processing step 223 determines whether or not the terminal voltage of the battery 3 has dropped below the detection voltage Vd before the switch-on. If it has decreased, in processing step 260, the remaining capacity of the battery 3 at the time of the detection voltage Vd value is referred from the program memory 182, and in the processing step 224, the work memory 189
Is changed to the remaining capacity.

In processing step 225, the detection information of the terminal voltage drop detection circuit 185 is reset.

Next, in processing steps 226, 227 and 228, the timer inside the CPU 176 is initialized. This initialization allows the CPU 176
Executes the charge capacity calculation program 229 by a timer interrupt at a fixed period.

If the terminal voltage of the battery 3 drops below the detection voltage Vd value of the terminal voltage drop detection circuit 185 during the execution of the charge capacity calculation program, the process shifts to a terminal voltage drop processing program in processing step 230.

Next, referring to FIG.
Will be described. The CPU 176 executes functions such as charging capacity setting means.

Processing steps 254 and 255 detect the terminal voltage drop and confirm the terminal voltage drop.

If the voltage has decreased, first, the remaining capacity of the battery 3 at the time of the detection voltage Vd value is referred from the program memory 182 in the processing step 256, and the work memory 189 is determined in the processing step 257.
Is changed to the remaining capacity.

A processing step 258 determines whether the AC adapter 1 is connected and charged. If the battery is not charged, the terminal voltage of the battery 3 drops sharply.
When the voltage falls below the operation limit voltage of 5, the CPU 176 enters the reset state, and enters the initial state in which the battery 3 is not charged.

FIG. 11 shows a program 22 for calculating the charge capacity by timer interrupt.
9 shows an integration process of an increase in the battery capacity due to charging, which is performed by 9. The CPU 176 executes functions such as charging capacity calculation means, consumption capacity calculation means, and charging current switching means.

First, in processing step 232, the current consumption value of the charging capacity calculation device 180 is referred to from the program memory 182, and in processing step 233, the converted consumption capacity = current consumption × interruption time interval Convert to the amount corresponding to the consumed capacity.

In processing steps 234 and 235, the state of charge of the charging circuit 2 is detected, and it is determined whether or not charging is in progress.

If the battery is being charged, the processing step
Reference the total charge capacity stored in 89. In the processing step 238, the saturation charge capacity of the battery is referred from the work memory 189. In processing step 239, the current total charge capacity and the saturation charge capacity are compared.

If (total charge capacity value ≦ saturated charge capacity value), the elapsed time is reset in step 302, the charge current is set to the normal charge current in process step 241, and the process proceeds to process step 242.

In the processing step 242, the conversion is made into an amount corresponding to the increase in the battery capacity due to charging, based on the time interval of the timer interruption, as converted charging capacity = constant current value of the charging circuit 2 × interruption time interval. Next, in processing step 243, the total charging capacity of the work memory 189 + the converted charging capacity of the processing step 242−the converted consumption capacity of the processing step 233 is calculated, and in the processing step 244, the total charging capacity of the work memory 189 is updated. I do.

On the other hand, if the charging is not performed from the AC adapter 1 in the processing step 235, the total charging capacity of the work memory 189−the converted consumption capacity in the processing step 233 is calculated in the processing step 236, and the memory capacity of the memory is calculated in the processing step 244. Update the total charge capacity.

If it is determined in the processing step 239 that the battery 3 has reached the saturation capacity, the elapsed time in the memory is updated in a step 301 with reference to the elapsed time in the memory in a step 300. A timekeeping area is set at an appropriate place in the work memory 189, and when the saturation capacity is reached for the first time, timekeeping is started and reset at step 239.

Then, in processing step 261, it is checked whether or not a predetermined time has elapsed, and if it has elapsed, in step 240, the charging is switched to minute charging. On the other hand, if the fixed time has not elapsed, the process proceeds to step 245, and the process is continued. Thereafter, in this routine, the above-described determination is made, and at a point in time when a certain period of time has elapsed, switching to the minute charging is performed as described above.

From the above, the total charge capacity value of the work memory 189 is
It is always updated to the latest remaining capacity value. In this state, the load consumption capacity calculation program of the processing step 245 is executed.

Next, the consumed capacity calculation program 245 will be described with reference to FIG. The CPU 176 executes functions such as a consumed capacity calculating unit, a remaining capacity calculating unit, and a charged capacity setting unit.

The processing step 247 refers to the current consumption value of the current consumption detection circuit 186. In processing step 248, the presence or absence of current consumption is determined, and if current is consumed, processing step 25
At 0, the converted consumption capacity = current consumption value x interrupt time interval, and converted to the amount corresponding to the consumption capacity. In processing step 251, the total charging capacity of the work memory 189 is calculated by subtracting the converted consumption capacity, and in the processing step 252, the total charging capacity of the work memory 189 is updated.

The document editing processor 170 connects to the bus via the bus charge, which updates the total charge capacity of the work memory 189, the voltage state of the storage battery by the terminal voltage drop detection circuit 185, and the presence / absence of charge by the charge detection unit 178. Reference is possible via circuit 187.

By the above means, the calculation of the increase in the battery capacity due to the charging of the battery and the calculation of the predicted consumption capacity are performed, and the remaining capacity of the battery is calculated. Thereby, the remaining capacity of the battery can be grasped, and the discharge life of the battery can be predicted.

Further, the document editing processing device 170 refers to the remaining capacity of the battery, the voltage state of the storage battery, and whether or not the battery is charged via the bus connection circuit 187, so that the user can check the remaining capacity of the battery and the voltage drop of the battery. Can be notified of a crisis condition, and the operable time can be calculated from the remaining capacity.

Further, the correction of the accumulated error by the calculation of the remaining capacity can be performed when the terminal voltage of the battery decreases and when the charge saturation capacity is reached. In addition, it is possible to prevent overcharging in the saturated charging state and improve the reliability of the device.

Although the embodiment of the document editing apparatus and the embodiment of the battery power supply system connected to the document editing apparatus have been described above, the present invention is not limited to these, and can be applied. Further, the battery power supply system does not have a unique display means, but it can be provided.

[Effects of the Invention] As described above, according to the present invention, a battery having a characteristic in which a terminal voltage changes abruptly at the end of discharge life, such as a nickel cadmium battery, used in a handy type document editing processing device or the like. By calculating how much charge capacity the battery currently has, the remaining capacity of the battery can be predicted. Then, the result is notified to the user, and the usability can be improved.

Furthermore, it is possible to determine whether or not the battery has a saturated charge capacity, and to add a function of switching to a minute charge if the battery has a saturated capacity, thereby preventing overcharging of the battery.

Further, a function of correcting error accumulation by calculating the remaining capacity can be added, thereby improving reliability.

[Brief description of the drawings]

1A and 1B are block diagrams each showing a configuration of an information processing apparatus according to the present invention, FIG. 2A is a main body block diagram of a document editing processing apparatus according to an embodiment of the present invention, and FIG. FIG. 3 is a block diagram showing an example of a circuit, FIG. 3 is a graph showing a discharge characteristic of a battery, FIG. 4 is a block diagram showing a configuration of a document editing process program, FIG. 5 is a document editing process flowchart, and FIG. FIG. 7 is a flowchart of a command mode execution availability determination process, FIG. 8 is a flowchart of a terminal voltage lowering process, and FIG. 9 is an overall configuration showing an example of a battery power supply system according to another embodiment of the present invention. Block diagram, FIG. 10 is an initial state processing flowchart, FIG. 11 is a charging capacity calculation processing flowchart, FIG.
FIG. 12 is a flowchart of a consumed capacity calculation process, and FIG. 13 is a flowchart of a terminal voltage lowering process. 2 ... Charging circuit 3 ... Battery 4 ... Power supply device 5 ... Main control circuit 6 ... Printer 7 ... Floppy disk device 9 ... Display 22 ... Central processing unit 23 ... Charge detection unit 91 ... Elapsed time Circuit B 92: Aging circuit A 121: Terminal voltage drop detection circuit

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hitoshi Yonega 1-1-1, Higashitaga-cho, Hitachi City, Ibaraki Prefecture Inside the Taga Plant of Hitachi, Ltd. (56) References JP-A-63-101785 (JP, A) JP-A-61-237073 (JP, A) JP-A-63-214816 (JP, A) JP-A-62-181138 (JP, U) JP-A-62-182641 (JP, U) (58) Int.Cl. ⁶ , DB name) G06F 1/26-1/32 H02J 7/00

Claims (17)

(57) [Claims] 1. An information processing apparatus comprising: a rechargeable battery serving as a power source of hardware constituting a system for performing information processing; and a charging unit for charging the battery, wherein the capacity of the battery is A battery management unit for predictive management is provided. The battery management unit detects whether or not charging is in progress, and if charging is in progress, determines a charging time, and increases the battery capacity due to charging from the charging time and the charging current. Charge capacity calculating means for calculating the minutes, consumed capacity calculating means for calculating the estimated consumed capacity supplied by the battery from the average used current and the used time required to execute the processing instructed in the system, and the battery by the charging An information processing apparatus comprising: a remaining capacity calculating unit configured to calculate a reduced amount of a remaining capacity of a battery from an increased capacity and a predicted consumption capacity. 2. An information processing apparatus comprising: a rechargeable battery serving as a power source of hardware constituting a system for performing information processing; and a charging unit for charging the battery, wherein the capacity of the battery is A battery management unit for predictive management is provided. The battery management unit detects whether or not charging is being performed. If charging is being performed, the remaining capacity and charging time at that time are obtained, and the charging time and charging current are determined. A charge capacity calculating means for calculating an increase in battery capacity due to charging; and a consumption capacity for calculating a predicted consumption capacity supplied by the battery from an average current and a usage time required for executing a process instructed in the system. Calculating means for comparing the difference between the increase in the battery capacity due to the charge and the difference between the predicted consumed capacity and the obtained remaining capacity to determine whether or not the process can be executed and to output the determination result The information processing apparatus characterized by being configured to have a line determination unit. 3. A rechargeable battery connected to a load and serving as a power source thereof, a charging unit for charging the battery, and a battery management unit for predicting and managing the capacity of the battery. In the battery power supply system, the battery management unit detects whether or not charging is being performed, and if charging is being performed, determines a charging time, and calculates an increase in battery capacity due to charging from the charging time and the charging current. A charging capacity calculating means for calculating, from the average usage current and usage time of the load, a consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery; and an increase in the battery capacity due to the charging and a predicted consumption capacity. And a remaining capacity calculating means for calculating a decrease in the remaining capacity of the battery. 4. A rechargeable battery connected to a load and serving as a power source thereof, a charging unit for charging the battery, and a battery management unit for predicting and managing the capacity of the battery. In the battery power supply system, the battery management unit detects whether or not charging is being performed, and if charging is in progress, obtains a remaining capacity at that time and a charging time, and determines from the charging time and the charging current: Charging capacity calculating means for calculating an increase in battery capacity due to charging; consumption capacity calculating means for calculating predicted consumption capacity supplied by the battery from the average use current and use time of the load; and Comparing the difference between the increase and the estimated consumed capacity with the determined remaining capacity to determine whether the operation of the load is executable, and outputting the determination result; It is characterized by comprising Pond power system. 5. A battery management device capable of charging and predicting and managing the capacity of a battery connected to a load and serving as a power source, wherein the battery management device detects whether or not charging is in progress, and Means for calculating a charging time and calculating an increase in the battery capacity due to charging from the charging time and the charging current; and a predicted consumption supplied by the battery from the average used current and the used time of the load. A consumption capacity calculating means for calculating the capacity; and a remaining capacity calculating means for calculating a decrease in the remaining capacity of the battery from the increase in the battery capacity due to the charging and the predicted consumption capacity. Battery management device. 6. A battery management device that is capable of charging and predicts and manages the capacity of a battery connected to a load and serving as an electric power source. Is the remaining capacity at that time, and the charging time, the charging time and the charging current, from the charging time, the charging capacity calculating means to calculate the increase in battery capacity due to charging, from the average usage current and usage time of the load A consumption capacity calculating means for calculating a predicted consumption capacity supplied by the battery; a difference between an increase in the battery capacity due to the charging and a difference in the predicted consumption capacity; and the obtained remaining capacity, and the operation of the load is executed. A battery management device comprising: an execution availability determination unit that determines whether or not the determination is possible and outputs the determination result. 7. When the determination result of the execution possibility determination means is not executable, it is necessary to calculate a time required for an increase in battery capacity due to the charging to exceed an estimated consumption capacity, and to output the calculation result. The information processing apparatus according to claim 2, further comprising a charging time calculating means, the battery power supply system according to claim 4, or the battery management apparatus according to claim 6. 8. The information processing apparatus according to claim 1, further comprising a saturation charging time calculating means for calculating a charging time required to reach a saturated charging capacity when charging the battery and outputting the calculation result. The battery power supply system according to claim 3, 4 or 7, or the battery management device according to claim 5, 6 or 7. 9. When the charging current can be switched,
It is characterized in that it comprises a charging current switching means for comparing a predetermined saturated charging capacity of the battery with the calculated increase in battery capacity due to the charging, and switching the charging current to a small current when the latter is large. The information processing apparatus according to claim 1, 2, 7, or 8, the battery power supply system according to claim 3, 4, 7, or 8, or the claim 5, 6, 7,
Or the battery management device according to 8. 10. When the charging current can be switched, a preset saturated charging capacity of the battery is compared with the calculated increase in battery capacity due to charging. 9. The information processing apparatus according to claim 1, further comprising a charging current switching unit configured to switch a charging current to a minute current after a predetermined time has elapsed. The battery management system according to claim 5, 6, 7, or 8, 11. A voltage drop detecting means for detecting a terminal voltage drop of a battery in a voltage range higher than an operation limit voltage, and an operable time from the detection point to an operation limit voltage is converted into a load corresponding value. And operable time conversion means for outputting the conversion result.
The information processing apparatus according to claim 2, 7, 8, 9, or 10, the battery power supply system according to claim 3, 4, 7, 8, 9, or 10, or the information processing apparatus according to claim 5, 6, 7, 8, 9, or 10. Battery management device. 12. A battery voltage drop detecting means for detecting a battery terminal voltage drop in a voltage range higher than an operation limit voltage, and detecting a battery terminal voltage drop when the battery terminal voltage drop is detected, the battery remaining capacity of the battery being set in advance. And a charge capacity setting means for changing and setting the charge capacity calculation means as a remaining capacity.
An information processing apparatus according to claim 11, wherein the information processing apparatus is an information processing apparatus.
12. The battery power supply system according to claim 11, or the battery management device according to claim 5, 6, 7, 8, 9, 10, or 11. 13. A central processing unit which is a component of hardware constituting a system in which the battery management unit performs information processing, a program memory for storing a data processing program executed by the central processing unit, and a work memory. Claims 1, 2, and 3 comprising:
The information processing apparatus according to 7, 8, 9, 10 or 11. 14. The information processing apparatus according to claim 2, further comprising a display unit for displaying a determination result of said execution availability determination unit, the battery power supply system according to claim 4, or the battery management device according to claim 6. 15. A required charging time calculating means for calculating a time required for an increase in battery capacity due to charging to exceed an estimated consumed capacity when a result of the determination by the feasibility determining means is not feasible; The information processing apparatus according to claim 2, further comprising a display unit for displaying a result, the battery power supply system according to claim 4, or the battery management apparatus according to claim 6. 16. Saturated charging time calculating means for calculating a charging time until reaching a saturated charging capacity when charging a battery;
A display unit for displaying the calculation result,
The information processing apparatus according to claim 2 or 7, the battery power supply system according to claim 3, 4, or 7, or the battery management apparatus according to claim 5, 6, or 7. 17. A voltage drop detecting means for detecting a battery terminal voltage drop in a voltage range higher than an operation limit voltage, and an operation for converting an operable time from the detection point to the operation limit voltage in correspondence with a load. And a display unit for displaying the conversion result.
9. The information processing apparatus according to claim 9 or 10, wherein
11. The battery power supply system according to claim 8, 9 or 10, or the battery management device according to claim 5, 6, 7, 8, 9 or 10.