KR960013534B1 - Fuel charging recognition method of the battery - Google Patents

Abstract

a medium connection detecting process(ST100) of detecting the connection of an adapter and a battery in the first stage; a first voltage change operating process(ST101) of averaging the charged voltage of the battery and storing the average voltage to a first maximum buffer; a second voltage change operating process(ST102) of averaging and storing the average voltage to a second maximum buffer after delaying; a difference voltage operating process(ST103) detecting by comparing the difference voltage of the two average voltages stored in the buffers with the set voltage; and a full-charge recognizing process(ST104) recognizing the voltage as a full-charge when the difference voltage is below the set voltage and performing a full-charge routine of the battery, and otherwise performing the processes(ST101,ST102).

Description

How to recognize the battery full charge

The present invention relates to a battery charge recognition in a notebook computer, and in particular, the voltage of the battery is read for a certain number of times at a certain time interval, the average value is obtained and stored, and the battery voltage is read for a predetermined number of times at a predetermined time interval after a predetermined time delay. The present invention relates to a battery full charge recognition method for recognizing a full charge of a battery by calculating an average value and a previous average value and a current average value.

In general, the switching mode power supply (SMPS) of a notebook computer is composed of one piece of hardware, and the DC voltage converted from the adapter is transferred to each system by dropping or raising the voltage through a DC / DC converter. In order to use the notebook computer in a place where it can be used as a power source and the adapter cannot be used, the DC voltage converted from the adapter must be charged in the battery in advance.

In this case, when the DC voltage converted by the adapter is charged in the battery, the voltage output from the adapter is continuously charged while detecting only the voltage of the battery regardless of the voltage currently charged in the battery.

As described above, the power supply of the conventional notebook computer continuously charges regardless of the voltage currently charged in the battery. In this case, the battery is charged for a long time when the battery is almost exhausted. Since the charging time is delayed, and if the voltage is continuously applied to the battery during battery charging, there is a problem that the battery is not overcharged and a fire is caused by the thermal firecracker of the battery.

Therefore, an object of the present invention is to read and store the battery voltage at a predetermined time interval for a certain number of times, and then store and calculate the average value. Save the difference from the mean.

After that, the battery voltage is read again at regular intervals, compared with the difference voltage, and the result is recognized as a full charge when the result falls below a predetermined voltage, and the battery is fully charged to protect the battery from damage and peripheral circuits caused by the overcharge of the battery. It is to provide a full recognition method.

In order to achieve the object of the present invention, a method of detecting an initial connection between an adapter and a battery is initially detected, and if the medium is connected, the average voltage is obtained by reading the battery's charging voltage at a predetermined time interval for a predetermined number of times. A first voltage change calculation process for storing in the maximum buffer, the average value is stored in the first maximum buffer, and after a predetermined time delay, the battery voltage is read at a predetermined time interval for a predetermined number of times, and the average value is obtained. A second voltage change operation stored in a buffer and a difference voltage for searching whether the subtracted difference voltage is less than or equal to the set voltage per battery of the battery by subtracting the average value stored in the first maximum buffer and the average value stored in the second maximum buffer If the difference is less than the set voltage during the calculation process and the search result, it is recognized as full charge and stops charging the battery If it is less than the first and second voltage change calculation process, it is recognized as full charge and stops charging of the battery. If it is abnormal, it repeats the first and second voltage change calculation process to recognize the full charge. This is achieved by being made, when described in detail below based on the accompanying drawings of the present invention.

1 is a schematic diagram of a battery full charge recognition system according to the present invention. As shown in FIG. 1, an adapter 100 for stepping down an input AC voltage and converting it into a DC voltage having an appropriate level is outputted from the adapter 101. Step-down and step-up of the converted DC voltage, and converts it to a constant voltage of a predetermined level, respectively, and supplies the DC / DC conversion means 101 for supplying the operating voltage of the system board 102, and the DC voltage of the adapter 100, A high signal is detected when the battery 103 to be discharged, the charging voltage detecting means 101 for detecting the voltage charged in the battery 103, and the connection between the adapter 100 and the battery 103 are connected. The adapter 100 and the battery detachment detecting means 107, 108 for outputting a low signal when disconnected, and the adapter 100 and the battery according to the output signal of the adapter, battery detachment detecting means 107, 108 Judging whether the battery 103 is connected The system control means 105 for controlling the battery charging by recognizing the charge amount of the battery 103 in accordance with the charge voltage of the battery 100 detected by the high charge voltage detection means 104, and the system control means 105 It consists of a charging drive means 106 including a transistor (TR1) (TR2) and a resistor (R1 = R4) is switched by a control signal according to the charge amount recognition to charge and cut off the voltage to the battery 103.

As shown in FIG. 2, the charging voltage detecting unit 104 receives the charging voltage of the battery 103 and amplifies the charging voltage to an arbitrary level, a resistor R5-R8, a differential amplifier OP1, and a diode D1. Amplifying a difference between the voltage amplification unit 104a including the voltage amplification unit 104a and the voltage amplified by the voltage amplifying unit 104a and the existing voltage of the power supply terminal Vcc to a predetermined level and inputting it to the system control means 105 And a differential voltage amplifier 104b including an R9-R11, a differential amplifier OP2, a capacitor C1, and a diode D2, D3.

FIG. 3 is a flow chart illustrating the battery full charge recognition signal according to FIG. 1. As shown in FIG. 1, a medium connection detection process (ST100) which initially searches for the presence of an adapter and a battery, and if the medium is connected, charge voltage of the battery. The first voltage change calculation process (ST101), which reads a predetermined number of times at regular time intervals, obtains an average value, and stores the average value in the first maximum buffer, and stores the average value in the first maximum buffer, and then recharges the battery at a predetermined time interval after a predetermined time delay The second voltage change calculation process (ST102) of reading the voltage of the predetermined number of times and obtaining the average value and storing the average value in the second maximum buffer, and subtracting the average value stored in the first maximum buffer and the average value stored in the second maximum buffer A differential voltage calculation process (ST103) for searching whether the subtracted differential voltage is lower than or equal to the set voltage per battery of the battery; A full charge recognition process (ST104) is performed to recognize the full charge by performing the full charge routine of the battery by recognizing the full charge on the high side and repeating the first and second voltage change calculation processes if the error is abnormal.

Thus, the operation and effect of the present invention configured in detail with reference to FIGS. 1 to 3 as follows.

First, when the adapter 100 and the battery 103 are connected to the system, the adapter 100 steps down the input AC voltage AC, converts the stepped AC voltage into DC voltage, and inputs the DC / DC conversion means 101. Done.

The DC / DC converting means 101 steps down and boosts the input DC voltage, and converts the step-down and stepped-up DC voltages into constant voltages of a predetermined level, respectively, to operate the 33V, -25V, and 3.3V on the system board 102. Supply voltage.

On the other hand, the battery 100 is converted into the adapter 100 to charge the input voltage, at this time, the adapter detachment detection means 107 and the battery detachment detection means 108 is the adapter 100 and the battery 103 The high signal is input when the adapter 100 and the battery 103 are connected to the system, and the low signal is input to the system control means 105 when the adapter 100 and the battery 103 are connected to the system.

Accordingly, the system control means 100 receives the high signal from the adapter detachment detecting means 107 and the battery detachment detecting means 108 through the medium connection detection process ST100 as shown in FIG. ) And when the battery 103 is connected, a count value (6 times) is stored in its own RAM through the first voltage change calculation process ST101 in order to recognize the charge amount of the battery 103 (ST3). In addition, the charged voltage of the battery 103 is read for a predetermined number of times at intervals of a predetermined time (2 minutes) through the charging voltage detecting means 104 and stored in its own RAM (ST4-ST6).

That is, the charging voltage detecting unit 104 is the differential voltage when the voltage charged in the battery 103 is input to the differential amplifier OP1 through the resistors R5, R6 and R7 of the voltage amplifier 104a. The amplifier OP1 amplifies the input voltage to an appropriate level and inputs it to the non-inverting terminal + of the differential amplifier OP2 through the resistors R9 and R10 of the differential voltage amplifier 104b.

The differential amplifier OP2 of the differential voltage amplifier 104b amplifies the difference from the reference voltage of the power supply terminal Vcc through the resistor R11 to remove the noise diode D2 (D3) and the resistor R13. By input to the system control means 105 through, the system control means 105, as described above, to store the voltage input from the charging voltage detection means 104 in its own RAM.

After that, it is searched whether the count value reaches a random number (ST7). If the random number has not been reached, the address of the RAM is increased until the random number count value is reached (ST8), and the process is repeated.

When the count value reaches the count value any number of times, the average value of the voltages read and stored for the random number is calculated (ST9) and the first and second maximum buffer flag states are searched (ST10) (ST11).

If the first maximum buffer flag is not set as a result of the search, the current average voltage obtained above is stored in the first maximum buffer (ST12) and the first maximum buffer flag is set.

When the first maximum buffer flag is set and the second maximum buffer flag is not set, the difference voltage between the average voltage currently obtained through the differential voltage calculation process ST103 and the previous average voltage stored in the first maximum buffer. (ST14), it is searched whether the obtained difference voltage is negative (ST15).

If the difference voltage has a positive value, the calculated average voltage is stored in the first maximum buffer (ST16), and a predetermined time (20 seconds) passes through the second voltage change calculation process (ST102). After the predetermined time has elapsed (ST17-ST19), the average voltage is obtained by reading the charging voltage of the battery 103 for a predetermined number of times at intervals of a predetermined time (2 minutes) through the first voltage change calculation process (ST101). The obtained average voltage is stored in the second maximum buffer.

If the difference between the current average voltage and the previous average voltage stored in the first maximum buffer has a negative value in the difference voltage calculation process ST103, the difference voltage having the negative value and the battery 103 of the battery 103 are set. The comparison with the voltage 7mV is performed (ST20).

When the difference voltage having a negative value is equal to or greater than the set voltage (7 mV) per cell, the second maximum buffer flag state is searched (ST21).

If the second maximum buffer flag is not set as a result of the search, the second maximum buffer flag is set (ST22), and the currently obtained average voltage is stored in the second maximum buffer (ST23), and then waited for a predetermined time (20 seconds). If the second maximum buffer flag is set, the current average voltage and the previous average voltage stored in the second maximum buffer are stored through the differential voltage calculation process ST103. The difference voltage with is obtained (ST24), and the calculated difference voltage is compared with the set voltage (7 mV) per battery of the battery 103 (ST25).

If the difference voltage is greater than or equal to the voltage set per cell, the first and second voltage change calculation processes ST101 and ST102 are repeatedly performed.

When the difference voltage drops below the set voltage (7 mV) per cell as a result of the search in the above steps ST20 and ST25, after the full charge is recognized through the full charge recognition process ST104, the charge drive means 106 The transistor TR2 is turned off (ST26) and the full charge flag is set (ST27) to perform the full charge routine to stop charging.

As described above in detail, the present invention reads the battery voltage at a predetermined time interval for a predetermined number of times, calculates and stores the average value, and reads the battery voltage for a predetermined number of times at a predetermined time interval after a predetermined time delay, and then transfers the previous value. By recognizing the full charge by the difference between the average value of the current value and the current average value, the battery is prevented from being overcharged, thereby preventing the battery from being destroyed by the thermal fire of the battery and damaging the peripheral circuit. There is an effect that can be prevented.

1 is a schematic diagram of a battery full charge recognition system of the present invention.

2 is a circuit diagram showing in detail the charging voltage detecting means of FIG.

3 is a battery full signal recognition signal flow according to FIG.

* Explanation of symbols on the main parts of the drawings

100: adapter 101: DC direct current conversion means

102: system board 103: battery

104: charging voltage detection means 105: system control means

106: charging driving means 107: adapter detachment detection means

Claims (6)

A medium connection detection process for initially searching for the presence of an adapter and a battery, and a first voltage change operation process for reading a battery's charge voltage at a predetermined time interval for a predetermined number of times, obtaining an average value, and storing it in a first maximum buffer. And a second voltage change calculation process of reading the voltage of the battery at a predetermined time interval for a predetermined number of times after storing the average value in the first maximum buffer, and obtaining the average value and storing the average value in the second maximum buffer. A difference voltage calculation process of comparing and subtracting the average value stored in the first maximum buffer with the average value stored in the second maximum buffer and comparing the subtracted difference voltage with a set voltage per battery of the battery; If it is below, it is recognized as full charge, and the battery performs a full charge routine. Battery full charge recognition method, characterized in that consisting of a full charge recognition process (ST104) to recognize the full charge. The method of claim 1, wherein the difference voltage in the difference voltage calculation process has a negative value. The method of claim 1, wherein when the difference voltage in the difference voltage calculation process is positive, the current average value is stored in the first maximum buffer, and the second voltage change calculation process is repeatedly performed after a predetermined time delay. How to recognize a battery full charge. The method of claim 1, wherein the voltage set per battery in the differential voltage calculation process is 7 mV. The method of claim 1, wherein the battery voltage reading in the first and second voltage change calculations is performed six times at two minute intervals. The method according to claim 1 or 3, wherein the predetermined time delay is 20 seconds.