JPH1115570A - Computer power managing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a computer power managing system by which a battery is normally kept in an optimum stand-by state. SOLUTION: The computer power managing system consists of a charging power source 12, a microprocessor 15, an oscillator 23, a pressure suppressing equipment 26, an input charging circuit 21, a pressure divider 22, an LCD 7, a data bus 14, a temp. control circuit connected to the data bus 14 and a smart battery 11. In the combination, a management controller by charging superiority is designed based on the defect of a notebook-type computer power system and the power of computer work is supplied by the battery perfectly.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a computer power management system, and more particularly to a computer power management system which can charge a battery to 100% until the battery is full while using the computer, and can recharge the battery under one condition. In addition, the battery is intermittently charged and the use of the portable computer is more convenient. This allows the battery to always maintain the best standby state, and increases the set of memory units and display devices around the battery, thereby improving the characteristics and characteristics of the battery.
A device that records and displays the number of times of use, the amount of stored electricity, the time of last use, identification data, etc.
ic input output system) on a computer screen.

[0002]

2. Description of the Related Art Batteries installed in conventional hand-held computers generally have a drawback that charging speed is slow. In order to meet the power supplier's own energy supply limitations, most planning schemes are such that when the computer is in use, the majority of the power supplier's energy is dedicated to the computer, and only a few are dedicated to battery charging. Have been For example, a general 30W (watt) power supply is designed for a computer to use 25W and a battery to use 5W. Under the condition that the computer is opened and used, even if the computer uses only 5W,
At this time, the battery can enjoy only the power of 5W, and the remaining 2
0W is wasted. Therefore, if the battery is 100%
Assuming that you have been using your computer for a long time without being charged, and then you need to carry the computer with you immediately, the battery cannot provide the computer with the theoretical capacity of the design at this time. Therefore, the efficiency of use of the computer is greatly reduced. This is a drawback in using batteries installed in conventional hand-held computers.

[0003]

In addition, conventional power suppliers should partition the two systems if they want to avoid interfering with or affecting the progress of computer use and charging. . In fact, power energy has been wasted in this way. For example, as shown in FIG. 1, a conventional computer and power supply mechanism converts an external AC power supply into a DC power supply that can be used by a computer mainly through an AC / DC converter 1, and outputs the power through two routes. One route is for charging the internal battery via the charger 2, and the other route is for the disk drive system 5, the CPU and the interface 6 via the DC-DC converter 3. And LCD
Power is supplied to an electric circuit mechanism such as 7. 2A per hour
(Amp) For an average load system assumed to be exhausted, two diodes are meaninglessly 2W in FIG.
Energy consumption, which accounts for almost 7% of the capacity of the battery 4 of a general hand-held computer, about 30 W,
This is a disadvantage in that the power supply is uselessly consumed.

A conventional portable computer power supply system as shown in FIG. 1 should output two sets of external AC / DC converters 1, one set of which is dedicated to the use of a computer. Another set is a power source for charging the battery 4. The time required for charging is often relatively long due to limitations on the volume and material of the battery, and the power dedicated to computer use is not always at full load. The direct current converter 1 has a drawback of low efficiency in use, and is designed for a load that can be used at full load. And, the diode mounted in the handheld computer, the depleted power supply further reduces the efficiency of the power supply, and in the case of the 586 computer system conventionally used universally, the + 5V (volt) power supply is used. Below requires 2-4 A of current, which consumes unnecessary power with diodes. As described above, the conventional method is not an ideal design in view of cost, efficiency, and charging speed.

[0005] Also, relatively new batteries dedicated to hand-held computers generally have a set of battery capacity indicators mounted therein to determine the remaining capacity of the battery, the amount of time it can be used, the number of uses, and the specified capacity. By providing the information, it is convenient for the user to grasp and control the instantaneous state of the battery at any time, and it is possible to avoid disadvantages such as a power failure or a stoppage of use without warning in advance.
However, the cost of this type of capacity indicator is very high, accounting for 1/5 to 1/3 of the total cost of the battery, and the battery itself is a consumable item, and when the life of the battery expires, these increased costs In addition, the devices are wasted and eliminated as the batteries age, which not only does not meet the demand for cost reduction, but also increases the burden on environmental protection. Also, this type of capacity indicator has too many parts and the space inside the battery itself is limited, which not only increases the manufacturing difficulty, but also reduces the reliability of the product. If the battery is left uncharged for a certain period of time, and if the battery is not continuously charged, the battery may be used due to "self-discharge" (one of the electrochemical characteristics) and the power consumption of the capacity indicator itself. When there is no electricity, the capacity indicator also loses the stored data because the battery can no longer supply the voltage, thus losing all the data that can be provided by this smart battery, and the user loses the original Battery material, standard, life,
Unable to know the original material such as capacity, causing a great deal of trouble in terms of use and convenience, and losing the significance and effectiveness of the original design.

In addition, the portable computer has a limit in the capacity of the battery itself, and the limited energy in the battery continues to be wasted in order to increase these additional effects. Not a design.
Speaking of the amount of electricity consumed by a one-piece PCB (Polychlorinated biphenyl) board (about 15-20 mA daily), the amount of electricity consumed is limited by the "self-discharge" in the battery for the limited capacity in the battery. More and more, the drawbacks of conventional designs become more apparent and need to be improved.

It is an object of the present invention to provide a computer power management system that always keeps the battery in the best standby state.

[0008]

SUMMARY OF THE INVENTION In view of the above-mentioned disadvantages of the conventional portable computer power supply application system, the present applicant has continually studied and improved the present invention, and has completed the present invention. The computer power management system of the present invention has a charge-priority management control device, and the power required for computer work is completely supplied by a battery, so that there is an immediate effect of an uninterruptible system, and the power supply is a battery. Only after going through the computer hardware part,
When power is applied, surges and noise are prevented from entering the hardware, and situations that affect the accuracy of data execution are completely prevented. The external DC-DC converter can be charged with the output of only one power supply, which saves cost and improves charging efficiency. The controller can charge the battery at any time, so that the battery always keeps the best standby state. If the power supply is 30W, another 25W when the computer consumes only 5W.
W can be used as energy for charging, thereby increasing the efficiency of charging and shortening the time required for charging.

[0009] Another advantage of the present invention is to provide a battery capacity memory and display device.
In particular, it is an object of the present invention to increase the number of memory units and display devices in a battery so that the characteristics of the battery, the number of times of use, the amount of stored power, the time of last use, identification information, etc. can be recorded and displayed. When the battery is charging or the computer transfers energy, this process can be recorded and updated via the memory unit, and the latest status can be shown at any time for the user's reference, It has the advantages of low cost, low cost, easy manufacturing, high reliability, etc., and can meet the needs of more users.

[0010]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 2 is a structural diagram of the present invention and a computer arrangement. As shown in the figure, the DC-DC converter 3 inside the handheld computer 20 uses only one set of output power supply as a power supply for charging. The output of the power supply is obtained via an AC-to-DC converter 1 to convert an external AC power supply to a DC power supply and via a power supply control device 8. The power controller 8 is connected to a smart battery (Intelligent Battery Pack) 11 having a memory unit and a display device via a data bus 14 at any time.
Is charged and the information is displayed, so that the smart battery 11 is always kept in the best electric energy saturated state. The smart battery 11 supplies power directly to the DC / DC converter 3 via the data bus 14 and the control device 8, thereby saving the power consumption caused by the two diodes conventionally used. . By using the power supply controller 8, the AC / DC converter 1 charges the smart battery 11 to 100% efficiency while using the computer. Under another condition, the smart battery 11 is recharged. Normally, the smart battery 11 is intermittently charged and indicates the state of charge storage, so that the smart battery 11 always keeps the best standby state, thereby making the use of the handheld computer 20 more convenient. I have. Since the control device 8 and the smart battery 11 are connected through the data bus 14 and are thus replaced with a conventional battery capacity indicator system, when designing this effect, only the original battery 4 is included in the original battery 4. The number of memory units 27 and the number of display devices 28 shown in FIG. This memory unit 27 is a kind of EEPROM
And a decoder, which normally sleeps when in standby and does not consume any power or battery energy. If the smart battery 11 has not been used for a very long time, the memory unit 2
Material 7 does not disappear. The memory unit stores the battery material, brand, manufacturing date, battery charge, the number of times the battery has been used, the current capacity of the battery, the last use time, battery identification information, and the like. When the smart battery 11 is charged, the accumulated energy of the battery is transmitted and stored in the memory unit, and also when the smart battery 11 transmits energy data to the computer, the memory is stored in the memory unit.
The value of the charge on the unit can also be updated and modified so that the charge in the smart battery is always up-to-date and accurate.

When the smart battery 11 is away from the computer or is resting (shut), the memory unit 27 stores the last used time, eg, year,
Record materials such as month, day, hour, minute, second, etc., and use them as the basis for updating the materials when using next time. Since the batteries of different manufacturers have different self-discharge rates, all information is used based on the identification material on the smart battery 11 to modify the amount of charge to meet the needs of actual use.

FIGS. 3 and 4 are flow charts of charging control according to the present invention. As shown in FIG. 3, the microprocessor itself has a certain control sequence, and starts charging when the AC / DC converter converts an external AC power supply to a DC power supply (30). It is detected whether the voltage value is lower than 1.2 V or higher than 1.5 V (31). If the battery voltage value is not lower than 1.2 V or higher than 1.5 V, it is considered that the battery is in a normal state, and the process proceeds to node A in FIG. If the battery voltage is lower than 1.2V or higher than 1.5V, it is considered that the battery has a problem and the battery is intermittently charged without continuously charging (32), and the voltage is again reduced to 1.2V.
And between 1.5V and 1.5V (33). If the voltage is between 1.2V and 1.5V, it is considered that the battery is in a normal state, and the process proceeds to the node A in FIG. 4; (34), and if the number of times to be detected has already been reached, it is determined that the battery has failed, and the battery is not intermittently charged (35). If charging voltage is 1.2
If it is below V or above 1.8V, it is assumed that there is a problem with the battery and charging will be aborted and a fault display will be displayed, informing the user that this battery no longer applies and should be replaced immediately.

After completing the voltage detection determination, if the detected battery is normal, the process proceeds to node A in FIG. 4, and it is detected again whether the charging current has increased (41). If not, it is detected continuously until it rises, and it is again detected whether the rise current is lower than the set minimum limit value (4).
2). If it is not lower than the minimum limit, the battery is continuously detected until it becomes lower than the minimum limit. At this time, charging of the battery is completed (43), and charging is performed every n seconds for n / 5 seconds (44).
It is detected again whether the charging current is larger than the set maximum limit value (45). If it is not larger than the maximum limit value, it is detected continuously, otherwise, it is counted whether the set number of times to be detected has already been completed (46). If the maximum limit has already been reached, charging of the battery is started (47), and the process returns to the step of detecting whether the current is increasing (41).

FIG. 5 is a block diagram of an electric circuit according to the present invention. As shown in FIG.
Converts an AC power supply from the AC to DC converter 1 into a DC power supply, and generates a charging power supply 12 via a battery characteristic detecting circuit 10 (comprising an input charging circuit and a voltage dividing circuit). Charge 11 At the same time, the latest data is transmitted to the smart battery 11 via the data bus 14 via the battery characteristic detection circuit 10 and the microprocessor 15 to record the charge data and indicate the state of the battery. At this time, the battery characteristic detecting circuit 10 also supplies power to the load 9 (which indicates the handheld computer 20). The charging power supply 12 uses the microprocessor 15 and the battery characteristic detecting circuit 10 as a control circuit, so that the detected battery characteristic and the amount of electricity are calculated by LC
It is displayed on the computer screen through D7 or BIOS. At the same time, the latest material is stored in the memory unit. Since the microprocessor 15 and the battery characteristic detecting circuit 10 can control the smart battery 11 based on numerical data stored and retrieved at any time, the charging power supply 12 is completely
To keep the smart battery 11 in the best state of charge, and at the same time keep up to date with the battery.

FIG. 6 is a detailed electric circuit of FIG. FIG.
As shown in FIG.
5, input charging circuit 21, voltage dividing circuit 22, quartz oscillator 2
3. Includes a manostat 26, LCD 7, smart battery 11 and temperature control circuit 24 connected to it (shown in FIG. 10). At the time of charging, the charging circuit 21 converts the output current value into a voltage value using a differential expander, and causes the microprocessor 15 to accurately calculate the change in the current value and the voltage value of charging and discharging, and the capacity. And the voltage input of the smart battery 11 is divided by a voltage dividing circuit 22, and then a single battery voltage is used as a reference of the input voltage, and pulse pre-charging is performed.
After g), if the voltage of the battery is lower than one value or higher than one value, the battery is regarded as having a problem and is not charged, and a fault is displayed on the LCD 7. The power supply of the microprocessor 15 is a pressure reducer 2
6, and the time sequence is generated by the quartz oscillator 23, thus providing a time pulse for intermittent charging. Another input is from the temperature control circuit 24 (see FIG. 10), which is the microprocessor 1
In step 5, the smart battery 11 determines charging conditions by changing the impedance of the temperature-sensitive resistor in the temperature control circuit 24 according to the change in temperature. The tangential ends of the material writing WR, the material reading RD, the material demand DQ, and the like are separately distributed in the microprocessor 15, and the smart battery 11 is provided.
The memory units 27 are connected to each other to achieve the purpose of data storage and retrieval and control.

FIG. 7 shows another embodiment of FIG. As shown in FIG. 7, the difference from FIG. 6 is the LCD (liquid cristal
display 7 is replaced by an LED (liquid emitting display) 25. FIG. 8 is an electric circuit diagram of the memory unit and the display device of the smart battery according to the present invention. Smart battery 11
Are connected to the memory unit 27 from both ends of the battery 4, and the memory unit 27 is
M and a decoder, and a display device 28 composed of an LED or LCD indicating the capacity of the battery 4 is connected to the outside thereof. Outside of this, the material writing WR (write) and the material reading RD (rea
d), has a connection end for data demand DQ (data request),
Thus, it is connected to the microprocessor 15 to achieve the purpose of data storage and retrieval and control. V in FIG. 8 represents a voltage source and supplies the operating voltage of the memory unit 27 and the display device 28. T represents a temperature measurement point, and measures a change in battery characteristics during charging or a temperature rise due to abnormal charging for the purpose of temperature protection and determination of charge saturation. SW indicates a button switch 29. When the system itself is shut down or a power failure occurs, or when the smart battery itself is not on the computer, the memory unit 27 is operated using the button switch 29.
And the state of the capacity of the battery itself is shown.

FIG. 9 is a memory unit control flow chart according to the present invention. When the computer is openly used (80), the microprocessor first determines whether a smart battery is already installed on the peripherals of the computer (81), and if not, the smart battery. Continue to judge until is installed. Also, after installing the smart battery,
First, after reading the basic data on the smart battery, charging is started (82), and then the charge amount of the smart battery is corrected every n hours and stored in the memory unit (83). If the battery is in a charged state, the charged amount is continuously increased until it becomes full. In the opposite case, that is, if power is supplied to the computer and peripheral equipment (ie, discharged), the charged amount is decreased (84). ),
At this time, the parameters are adjusted according to the brand, capacity and usable time of the smart battery (85), and the time and capacity are transported into the memory of the smart battery to update the data (86), and the smart battery is updated.・ Allow the battery to keep the latest numerical data, use it for reference, and finally repeat the entire flow and execute it.

[0018]

As described above, the present invention enhances the efficiency of the portable computer power control and the battery to reduce the cost without consuming electric energy, and the cost of the battery capacity indicator is reduced to the original design. 1/10, easy to manufacture, extremely reliable, very good design. The present invention allows the battery to be charged, recorded and displayed at any time, allows the smart battery to maintain its best condition, and the smart battery directly supplies power to the DC to DC converter, resulting in two diodes. To save power consumption, among the control devices according to the present invention, the AC to DC converter is 100% until the battery (BatteryPack) becomes full while using the computer.
It can charge the battery efficiently, recharge the battery under one condition, intermittently charge the normal battery, and use a portable computer (Note Book Compute
Make the use of r) more convenient. In addition, the memory unit is at its best, so it is asleep during standby and does not drain any power or battery energy. If the smart battery is not used for a very long time and is discharged to zero voltage, its data will not be lost and the battery material, brand, manufacturing date and battery stored in the memory will not be lost. The amount of battery, the number of times the battery has been used, the current capacity of the battery, the last
When the battery is charged, the accumulated energy of the battery is transmitted and stored in the memory unit, and the smart
When the battery is transferring energy to the computer, the value of the charge in the memory unit can be updated and corrected, the value of the charge in the smart battery can be displayed at any time, the latest information can be displayed, Practicality and convenience.

As mentioned above, the computer power management system of the present invention provides an effective solution in accordance with the shortcomings of commonly used power management systems and battery capacity indicators, and allows more computer users. Can be felt convenient and practical,
It complies with the requirements of the invention claims. It should be emphasized that what has been described above belongs only to the depiction of the relatively ideal embodiment of the present invention, and that the results arising from some changes or modifications of the general description may be those of the specification and the accompanying drawings. If the spirit of the present invention is not exceeded, it is considered that all the claims are included in the claims of the present invention.

[Brief description of the drawings]

FIG. 1 is a structural diagram of a conventional computer and power supply.

FIG. 2 is a structural diagram showing an arrangement of a computer according to an embodiment of the present invention;

FIG. 3 is a flow chart of charging control according to the embodiment.

FIG. 4 is a flow chart of charge control according to the embodiment.

FIG. 5 is a block diagram of an electric circuit according to the embodiment.

FIG. 6 is a detailed electric circuit diagram according to the present embodiment.

FIG. 7 is an electric circuit diagram showing another embodiment different from FIG. 6;

FIG. 8 is an electric circuit diagram of a memory unit and a display device of the smart battery according to the embodiment.

FIG. 9 is a flow chart of a memory unit control according to the embodiment.

FIG. 10 is an electric circuit diagram of temperature control according to the present embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 AC-DC converter 2 Charger 3 DC-DC converter 4 Battery 5 Disk drive system 6 CPU and interface 7 LCD 8 Controller 9 Load 10 Battery characteristic detection circuit 11 Smart battery 12 Charging power supply 13 External power supply 14 Data Bus 15 Microprocessor 20 Handheld Computer 21 Input Charging Circuit 22 Voltage Divider 23 Quartz Oscillator 24 Temperature Control Circuit 25 LED 26 Pressure Reducing Device 27 Memory Unit 28 Display Device 29 Button Switch

Claims (3)

[Claims] 1. A charging power supply, a smart battery, and a temperature control circuit connected to a microprocessor, an oscillator, a moderator, an input charging circuit, a voltage dividing circuit, an LCD, a data bus, and a data bus. The charging circuit converts the output current value to a voltage value using a differential magnifier during charging, and causes the control device to accurately calculate the charging current value and the voltage value; After the voltage is divided by the voltage divider circuit, a single battery voltage is used as an input voltage reference, and if the battery voltage is lower than one value or higher than one value after the pulsed last charge, a fault condition is detected. It is displayed on an LCD or other display device, and a quartz oscillator generates a time sequence of the control device, which is used as a time pulse for intermittent charging. The battery is used to change the impedance of the temperature-sensitive resistor in the temperature control circuit according to the temperature change, thereby judging the charging condition, and consists of a set of memory unit and display device around the battery A smart battery is provided, and the memory unit is interconnected with the microprocessor to record the capacity of the battery, the number of times of use, the remaining capacity, the usable time, the specified capacity, and the status of the existing capacity. This memory unit can update the internal memory data or read data at any time according to the state of charging or energy consumption when using the computer power management system, and can also store the internal data when the system is off The power control system saves the data in the memory unit until the next use. Computer Power Management System, characterized in that provides, as a basis for data references and documentation updates Te following. 2. The computer power management system according to claim 1, wherein said LCD can be replaced by an LED or another display element. 3. The battery memory unit according to claim 1, wherein
2. The computer power management system according to claim 1, further comprising an EPROM and a decoder.