KR0144383B1 - Charging control apparatus using remnant power - Google Patents

Abstract

The battery charge operation is performed by using an extra amount of power supplied from a low-power power supply during the operation of the portable computer, thereby reducing the battery charging time for carrying the portable computer and allowing the external to recognize the state of charge of the battery. In order to provide a charging control device for a portable computer using a low-power AC power supply for supplying a low power required for the operation of the computer system; Charging means for charging a voltage Vin input from the low power AC power supply device to the battery B + according to a switching operation of the switch means; Detects the current consumption of the low power AC power supply consumed by the portable computer system, and uses the voltage Vin output from the low power AC power supply when the current consumption is below the set value and the charge state of the battery B + is below the set voltage. And sensing means for outputting a control signal for executing the charging operation of the battery B +.

Description

Charge control device of portable computer using spare power

1 is a block diagram of a charging control device of a portable computer using a spare power according to an embodiment of the present invention.

2 is a detailed circuit diagram of a charging control device of a portable computer using the surplus power according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging control device of a portable computer using spare power. In particular, when the power consumption of the portable computer is low while the portable computer is in use, a margin for performing a charging operation of the battery using a voltage supplied from a low power AC power supply device is provided. A charging control device for a portable computer using electric power.

In general, portable devices are being manufactured in a very small size to input and output desired information regardless of time and place to enable rapid information processing and information communication, and user demand is increasing.

Therefore, a word processor or a portable computer, which is widely used as a portable device, can be used regardless of a place, and thus the power required for operation is driven by a low-power AC power supply device or a rechargeable battery for use in a portable device.

Therefore, when using a portable device when carrying or in a place where power is not supplied, the power of a rechargeable battery having a limited use time should be used.

Therefore, when using a rechargeable battery, a separate battery charging operation must be performed.

Therefore, in order to realize the charging operation of the rechargeable battery, when the charging operation of the rechargeable battery and the portable computer are operated by using the power generated in the low power AC power supply of the portable computer used, the power required for the operation is insufficient. .

Therefore, in the related art, in order to perform the charging operation of the rechargeable battery of the portable computer, the operation of the portable computer is stopped, and then the charging operation is performed using the low power AC power supply used or the charging operation of the battery using a separate external charger. Was run.

Therefore, in order to use the portable computer in a portable state as described above, the standby time must be as long as the charging time of the rechargeable battery, and since the battery is not equipped with a separate display device that can check the charging state from the outside, the current state of charge of the battery Unable to confirm the problem occurs.

Therefore, an object of the present invention is to solve the above-mentioned conventional problems, and the battery charging time for carrying a portable computer is performed because the charging operation of the battery is performed by using an extra amount of power supplied from the low power power supply device during the operation of the portable computer. Can be shortened.

In addition, another object of the present invention is to provide a charging control device of a portable computer using the extra power to allow the external to recognize the state of charge of the battery.

The configuration of the present invention for achieving the above object is a low power AC power supply for supplying a low power required for the operation of the computer system; Switching means for switching a voltage input from said low power AC power supply device; Charging means for charging the battery according to the operation; Detects the current consumption of the low power AC power supply consumed by the portable computer system, and when the current consumption is lower than the set value and the battery charge state is lower than the set voltage, the battery output operation is performed using the voltage output from the low power AC power supply. Sensing means for outputting a control signal for execution.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a charging control device of a portable computer using a spare power according to an embodiment of the present invention, Figure 2 is a detailed circuit diagram of a charging control device of a portable computer using a spare power according to an embodiment of the present invention.

Referring to the configuration of the present invention with reference to FIG. 1, a battery B + capable of charging operation, a low power AC power supply 1 for supplying low power required for the operation of a computer system, and the low power AC power supply ( The charging unit 2 which controls the charging operation of the battery B + using the voltage Vin input from 1), and the charging of the battery B + according to the charging state of the charging unit 2 or the consumption current of the portable computer. And a sensing unit 3 for controlling the state and a portable computer system 4 which operates using the low power AC power supply 1 or the charging power of the battery B +.

The charging unit 2 has a regulator 21 having an input terminal Vi connected to the low power AC power supply 1, and one terminal connected to the voltage compensating terminal Vc of the regulator 21 and the other terminal. Is connected to a capacitor (C21) that is grounded, a resistor (R21) that one terminal is connected to the output terminal (SW) of the regulator 21, and one terminal is connected to the low-power AC power supply (1) A resistor R22 having the other terminal connected to the other terminal of the R21 and a collector terminal having the collector terminal connected to the low power AC power supply 1 and the base terminal connected to the other terminal of the resistor R22. ), An MOS FET T22 having a source terminal connected to the collector terminal of the transistor T21, an anode terminal connected to a gate terminal of the MOS FET T22, and an emitter terminal of the transistor T21. The cathode terminal to the other terminal of the resistor (R21) Is connected to a diode D21 connected to the diode, a cathode terminal is connected to the drain terminal of the MOS FET T22, and an anode terminal is grounded, and one side is connected to the cathode terminal of the diode D22. One terminal is connected to a coil 21 having a terminal connected thereto, a capacitor C22 having one terminal connected to the other terminal of the coil L21, and the other terminal being grounded, and one terminal of the capacitor C22. A resistor (R23) connected to the resistor, a resistor (R24) having one terminal connected to one terminal of the resistor (R23), and a resistor (R25) having one terminal connected to the other terminal of the resistor (R23); A resistor (R26) having one terminal connected to the other terminal of the resistor (R24) and having the other terminal grounded, and a non-inverting terminal connected to the other terminal of the resistor (R24), and the other side of the resistor R26; Calculation of inverting terminal connected to terminal Aeration Q21, a resistor R27 having one terminal connected to the inverting terminal of the operational amplifier Q21 and the other terminal connected to the output terminal of the operational amplifier Q21, and the operational amplifier Q21 A resistor R28 having one terminal connected to the output terminal, a resistor R29 having one terminal connected to the other terminal of the resistor R28 and the other terminal being grounded, and the other terminal of the resistor R28. And a resistor R210 having one terminal connected to the feedback terminal FB of the regulator 21.

The sensing unit 3 controls the charging operation of the battery B + by sensing the diode D31 rectifying the current supplied from the battery B + and the charging voltage of the battery B + and charging the battery B +. It consists of a pre-cancer detection unit 31 for recognizing the state, and a current detection unit 32 for detecting the state of the current output from the low-power AC power supply 1 to control the charging operation of the battery (B +). .

The voltage detector 31 includes a light emitting diode LED311 having an anode terminal connected to a battery B +, a thyristor SRC311 having an anode terminal connected to a cathode terminal of the light emitting diode LED311, and a battery. A zener diode (ZD311) having a cathode terminal connected to (B +) and an anode terminal connected to a gate terminal of the thyristor (SRC311), a resistor (R311) having one terminal connected to a power source (Vcc), A drain terminal is connected to the other terminal of the resistor R311 and a gate terminal is connected to the anode terminal of the zener diode ZD311, and one terminal is connected to the anode terminal of the zener diode ZD311. A resistor R312 connected and the other terminal grounded, a resistor R313 connected to one terminal of the battery B +, and the other terminal connected to a cathode terminal of the thyristor SRC311; One terminal is connected to the other terminal of the resistor R313 and the other terminal is made of a resistor R314 grounded.

The current sensing unit 32 includes a resistor R421 having one terminal connected to the low power AC power supply 1 and the other terminal connected to the portable computer system 4, and a low power AC power supply 1. The comparator Q321 connected to the reference voltage Vref, a non-inverting terminal connected to the reference voltage Vref, and an inverting terminal connected to the other terminal of the resistor R321, and the comparator Q321. Inverter G321 having an input terminal connected to an output terminal, a resistor R322 having one terminal connected to an output terminal of the inverter G321 and the other terminal being grounded, and the voltage sensing unit 31 One input terminal is connected to the source terminal of the MOS FET T311, and the inverter G321 is connected to an AND terminal G322 having the other input terminal connected to the output terminal, and an anode connected to the output terminal of the AND gate G322. Diode (D321) connected to the terminal, and The resistor R323 having one terminal connected to the cathode terminal of the diode D321 and the other terminal being grounded, and the gate terminal connected to the cathode terminal of the diode D321 connected to the cathode terminal of the charging unit 2 A MOS FET T321 having a drain terminal connected to the other terminal of the resistor R210 and having a source terminal grounded, and a MOS FET having a gate terminal connected to the output terminal of the inverter G321 and grounded at the source terminal. T322, a resistor R324 having one terminal connected to the drain terminal of the MOS FET T322 and the other terminal being grounded, and one terminal connected to the low power AC power supply 1, and a MOS FET ( A resistor R325 having the other terminal connected to the drain terminal of T322 and a gate terminal connected to the other terminal of the resistor R325 and the voltage compensation terminal Vc of the regulator 21 of the charging unit 2 are connected. Drain terminal on Air and consists of a MOS FET (T323) with a source terminal is grounded.

The operation of the present invention made as described above is as follows.

When the low power AC power supply 1 is operated and a corresponding voltage Vin is supplied to the charging unit 2 and the sensing unit 3, the sensing unit 2 is charged according to the state of the low power AC power supply 1. ) Is controlled.

Therefore, the comparator Q321 of the current sensing unit 32 of the sensing unit 3 whose voltage value is varied by the voltage Vin output from the low power AC power supply device 1 has a reference voltage Vref of more than the set voltage. When the voltage is lower than the voltage of the battery B + applied through the diode D31, the output state of the comparator Q321 becomes L, which is a low level.

In other words, when the power consumption of the portable computer system 4 is low, the voltage across the resistor R321 decreases below the reference voltage value.

Accordingly, when the power consumption of the portable computer system 4 is low and the output signal of the comparator Q321 becomes L, which is a relevel, the high level H signal is applied to the gate terminal of the MOS FET T322 through the inverter G321. .

Therefore, the MOS FET T322 is changed to the turned on state, and the current of the voltage Vin flows through the turned on MOS FET T322 through the resistor R325, so the state of the MOS FET T323 is also turned off. Variable.

As the MOS FET T323 is changed to a turn-off state, the capacitor C21 connected to the voltage compensation terminal Vc of the regulator 21 is operated to operate the regulator 21.

The turn-on / off states of the transistors T21 and the MOS FETs T22 are changed according to the state of the pulse signal determined by the charge / discharge cycle of the capacitor C21 to the output terminal SW by the operation of the regulator 21. Variable.

Therefore, the voltage boosted by the coil L21 to the corresponding magnitude by the turn on / off operation of the MOS FET T22 is performed to charge the battery B + by the charge / discharge operation of the capacitor C22.

As described above, when the current consumed by the portable computer system 4 is lower than or equal to a set value, the charging state of the battery B + charged by the charging operation of the charging unit 2 is detected by the operation of the zener diode ZD311.

Therefore, when the charging voltage of the battery B + is higher than the set voltage of the zener diode ZD311, the zener diode ZD311 is turned on.

Therefore, since the voltage applied by the conduction operation of the zener diode ZD311 is applied to the gate terminals of the MOS FET T311 and the thyristor SRC311, the MOS FET T311 and the thyristor SRC311 are also changed to the on state. .

Since the light emitting diode LED311 is turned on during the turn-on operation of the thyristor SRC311, the charged state of the battery B + may be externally recognized as an operating state of the light emitting diode LED311 that is turned on / off.

Therefore, since the state of charge of the battery B + can be checked using the light emitting diode LED311, the damage of the battery B +, which may occur due to excessive charging operation, is prevented, and the state of charge of the battery B + is brought into an appropriate state. I can keep it.

The current of the power supply Vcc flows through the MOS FET T311 turned on by the conduction operation of the zener diode ZD311, so that a high level H is input to one input terminal of the AND gate G322 of the current sensing unit 32. Is entered.

At this time, when the amount of current consumed by the portable computer system 4 is equal to or less than the set value, the output signal of the comparator Q321 is L at the low level, and the signal at the output terminal of the AND gate G322 is H at the high level.

Therefore, the output signal of the AND gate G322 having a high level is input to the gate terminal of the MOS FET T321 through the diode D321, and the MOS FET T321 is changed to the turned on state.

By the turn-on operation of the MOS FET T321, a voltage varying according to the charging voltage state of the battery B + is fed back to the feedback terminal FB of the regulator 21 of the charging unit 2.

Therefore, the voltage applied to the resistor R23 of the charging unit 2 that varies according to the charging voltage state of the battery B + is a predetermined magnitude by the operation of the operational amplifier Q21 and the resistors R24 to R27 that operate as inverting amplifiers. Since it is amplified by, the voltage V1 output from the operational amplifier Q21 varies according to the charging voltage of the battery B +.

As described above, the voltage fed back to the feedback terminal FB of the regulator 21 is varied by the output voltage V1 and the resistances R28, R29, and R210 of the operational amplifier Q21 as shown in Equation 1 below. Current will flow.

The regulator 21 has a cycle of a pulse signal output to the output terminal SW according to a voltage fed back to the feedback terminal FB, and turns on / off transistors T21 and T22 according to the cycle of the pulse signal. Since the period is also variable, the charging voltage is adjusted according to the charging voltage state of the battery B +.

Therefore, when the charging operation of the battery B + is performed by using the extra voltage generated when the low current is applied to the portable computer system 4 as described above, the charge state of the battery B + is detected by the Zener of the sensing unit 31. When the battery is charged over the set value set by the diode ZD311, the battery B + is charged to the feedback terminal FB of the regulator 21 of the charging unit 2 by using the output signal of the AND gate G322 as described above. Since the feedback voltage is proportional to the state, the charging state of the battery B + can be adjusted.

Therefore, the charging state of the battery B + is changed by varying the Zener value of the Zener diode ZD311 of the sensing unit 3 and the value of the resistor R210 varying the feedback voltage of the regulator 21 of the charging unit 2. Can be adjusted in multiple stages.

However, when the current consumption of the portable computer system is large and the voltage Vref generated across the resistor R321 used as the current sensing device is higher than or equal to the set value, the output signal of the comparator Q321 becomes H, which is a high level.

Therefore, since the low level L is input to the other input terminal of the AND gate G322 and the gate terminal of the MOS FET T322 through the inverter G321, the output signal of the AND gate G322 becomes L at the low level, thereby providing the MOS FET ( T321 is turned off.

Therefore, the feedback voltage input to the feedback terminal FB of the charging section 2 is normally set by the operational amplifier Q21 and the resistors R27 to R29 to control the operation of the regulator 21.

However, the MOS FET T322 is also turned off by the output signal of the low-level inverter G321, and the MOS FET T323 is turned on by the voltage of the power supply Vin applied through the resistor R325.

A capacitor connected to the voltage compensation terminal Vc of the regulator 21 by varying the voltage compensation terminal Vc of the regulator 21 of the charging unit 2 to the ground state by the turn-on operation of the MOS FET T323. Since the charge / discharge operation of C21 is stopped, the operation of the regulator 21 is stopped.

Therefore, when a large amount of current is consumed by the use of the portable computer system 4 as described above, the operation of the regulator 21 is stopped so that the charging operation of the battery B + cannot be performed. Addresses issues that affect the use of portable computers due to lack of power.

The effect of this invention operating as described above is that when the voltage of the low power AC power supply is supplied to the portable computer system to use the portable computer, the charging operation of the battery is performed when the current consumption of the portable computer system is low. In addition, the battery charging time required for using the battery can be shortened.

In addition, since the state of charge of the battery may be determined by using the dot / off state of the light emitting diode, the state of charge of the battery may be maintained in an appropriate state, and damage to the battery due to excessive charging may be prevented.

Claims (7)

A low power ac power supply for supplying low power for operation of a computer system; Charging means for charging a voltage Vin input from the low power AC power supply device to the battery B + according to a switching operation of the switch means; Detects the current consumption of the low power AC power supply consumed by the portable computer system, and uses the voltage Vin output from the low power AC power supply when the current consumption is below the set value and the charge state of the battery B + is below the set voltage. And a sensing means for outputting a control signal for executing a charging operation of the battery B +. The apparatus of claim 1, wherein the sensing unit detects a charging state of the battery B + by using a Zener value of the Zener diode ZD311. The spare power according to claim 1, wherein the sensing means makes it possible to recognize the state of charge of the battery B + using the display means which is operated when the state of charge of the battery B + is equal to or greater than a set value. Charge control device of a portable computer using the. The apparatus of claim 3, wherein the display means uses a light emitting diode (LES311) whose point / lighting state is changed according to an operating state of the zener diode (ZD311). The pre-cancer detecting unit 31 of claim 1, wherein the sensing unit detects the charging voltage of the battery B + to control the charging operation of the battery B + and to recognize the charging state of the battery B +. Wow; The charging of the battery B + sensed by the voltage detector 31 when the current consumption from the low power AC power supply 1 is detected and the current consumed by the portable computer system 4 is lower than or equal to a set value. Charging control device of a portable computer using the extra power, characterized in that the current detection section 32 for outputting a control signal for controlling the operation of the charging means according to the state. The method of claim 5, wherein the voltage detector 31 includes a light emitting diode (LED311) having an anode terminal connected to a battery (B +), and an anode terminal connected to a cathode terminal of the light emitting diode (LED311). The thyristor (SRC311), the cathode terminal is connected to the battery (B +), the anode terminal is connected to the gate terminal of the thyristor (SRC311) and the drain terminal is connected to the power supply (Vcc) A transistor T311 having a gate terminal connected to the anode terminal of the zener diode ZD311, a resistor R312 having one terminal connected to the anode terminal of the zener diode ZD311, and the other terminal being grounded; One terminal is connected to the battery B + and one terminal is connected to the resistor R313 having the other terminal connected to the cathode terminal of the thyristor SRC311 and the other terminal of the resistor R313. The charging control device of a portable computer using the surplus power, characterized in that consisting of a resistor (R314), the other terminal is grounded. The portable terminal of claim 5, wherein the current sensing unit 32 includes a resistor R421 having one terminal connected to the low power AC power supply 1 and the other terminal connected to the portable computer system 4. A comparator Q321 having a non-inverting terminal connected to a reference voltage Vref having a variable voltage value according to a current consumption of the system 4, and an inverting terminal connected to the other terminal of the resistor R321; An inverting means G321 having an input terminal connected to an output terminal of Q321), and an input terminal of one side connected to a source terminal of the transistor T311 of the voltage sensing unit 31, and an output terminal of the inverter G321. A logical multiplication means (G322) having the other input terminal connected thereto, a diode (D321) having an anode terminal connected to an output terminal of the logical multiplication means (G322), and a cathode terminal of the diode (D321). The gate terminal is connected to the A transistor T321 having a drain terminal connected to the charging means and having a grounded source terminal, a transistor T322 having a gate terminal connected to the output terminal of the inverting means G321 and grounded at the source terminal; A resistor R325 having one terminal connected to the low power AC power supply and the other terminal connected to the drain terminal of the transistor T322, and a gate terminal connected to the other terminal of the resistor R325 and connected to the charging means. A charge control device for a portable computer using spare power, comprising a transistor (T323) having a drain terminal connected and a source terminal grounded.