KR20120069399A - A battery charging method - Google Patents

Abstract

PURPOSE: A battery charging method is provided to minimize time required for charging a rechargeable battery by not requiring an additional process and time corresponding to charging processes for arranging a half-charged state and a fully-charged state. CONSTITUTION: A controller outputs a discharged voltage equation as a function of time using a battery discharge curve(S100). A voltage sensor outputs residual voltage data by detecting current voltage of a battery(S200). A controller determines a voltage level which is less than a fully charged voltage level(S300). The controller calculates required charging time from the discharged voltage equation(S400). A charging unit charges a battery with 0.1V for 10 minutes in which the 0.1V is a voltage difference between current residual voltage and fully charged voltage(S500). A counter counts each battery charging process(S600). The controller determines the number of battery charging processes using the counter(S700). The controller determines malfunction of the battery(S800).

Description

Battery charging method {A battery charging method}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery charging method, and more particularly, to a battery charging method for minimizing the time required for charging when a rechargeable battery is self-discharged.

In general, the rechargeable battery is charged when there is a power supply from the power adapter to the electronics, and discharges while supplying the charged power to the electronics when operating the electronics with the power adapter separated.

In particular, secondary rechargeable batteries such as nickel metal hydride and lithium ions gradually consume a little charged current due to their characteristics even when they are not used, such as long-term inventory generation after purchasing the battery, which is called self discharge.

Therefore, most battery chargers on the market must be charged until they are fully charged by applying a predetermined voltage and current. In the case of battery manufacturers, the battery charger is fully charged during battery production for safety such as explosion risks during transportation. It is often filled in half charge rather than full charge and shipped to containers.

To this end, the conventional battery charging method completely discharges the battery and then charges the battery in semi-charged form again for a predetermined time, for example, 30 to 40 minutes in a high speed mode or a low speed mode.

However, in the conventional battery charging method, there is a need for additional time and additional work as long as the process for the full discharge and the process for charging in the form of semi-charge again.

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery charging method capable of charging a battery only by a required voltage at a calculated time without fully discharging by calculating a charging time using a battery discharge curve.

The battery charging method of the present invention for achieving the above object comprises the steps of: (a) calculating the discharge voltage equation using the discharge curve of the battery; (b) sensing the voltage of the battery and outputting residual voltage data; (c) calculating a charging time required from the discharge voltage equation when the residual voltage data is less than a predetermined full charge voltage; (d) charging the battery for the charging time required.

The battery charging method of the present invention for achieving the above object comprises the steps of: (e) increasing the number of charges of the battery after step (d); (f) receiving the number of charges and determining that the battery is defective when N or more.

N of the battery charging method of the present invention for achieving the above object is characterized in that 4 to 6 times.

N of the battery charging method of the present invention for achieving the above object is characterized in that five times.

The step (d) of the battery charging method of the present invention for achieving the above object is characterized in that the step of charging the battery with a voltage obtained by subtracting the residual voltage data from the full charge voltage.

The discharge curve of the battery of the battery charging method of the present invention for achieving the above object is characterized in that it can be obtained from a battery manufacturer or through repeated experiments.

Battery charging apparatus of the present invention for achieving the above object is a voltage sensing unit for sensing the current voltage of the battery and outputs the remaining voltage data; A counter for counting and outputting the number of charges of the battery; Calculate the discharge voltage calculation formula from the battery discharge curve, calculate the required charging time from the discharge voltage calculation formula by receiving the residual voltage data and compare it with a preset full charge voltage, and whether the battery is defective by receiving the charge count. A control unit for determining; And a charging unit configured to receive the charging required time and charge the battery during the charging required time.

The battery charging method of the present invention can minimize the time required for charging the rechargeable battery without the additional time and the need for additional work as a process for a full discharge and a process for charging in a semi-charged form again.

In addition, when long-term inventory occurs after the battery purchase, only a small amount of charge is reduced by the natural discharge is reduced, only the voltage can be efficiently charged from the full charge voltage minus the residual voltage.

1 is a schematic block diagram of a battery charging apparatus capable of optimizing battery charging according to the present invention.
2 is a flowchart illustrating an operation of a battery charging method according to the present invention.
3 is a graph of a battery discharge curve generated according to an embodiment of the battery charging method of the present invention.

Hereinafter, a battery charging method of the present invention will be described with reference to the accompanying drawings.

1 is a schematic block diagram of a battery charging apparatus capable of optimizing battery charging in accordance with the present invention. The battery 100, the voltage sensing unit 200, the control unit 300, the charging unit 400, and the counter 500 are illustrated in FIG. It is provided.

Referring to Figure 1 describes the function of each block of the battery charging apparatus according to the present invention.

The battery 100 is discharged while supplying a voltage for operating the host electronic device with a voltage to be charged.

The voltage detector 200 detects a current voltage of the battery 100 and outputs residual voltage data.

The counter 500 counts the number of charges in the battery 100 and outputs the number of charges.

The control unit 300 calculates the discharge voltage calculation formula using a predetermined statistical program from the battery discharge curve, calculates the required charging time from the discharge voltage calculation formula by comparing the residual voltage data with a preset full charge voltage, and calculates the counter ( The number of charges is applied from 500 to determine whether the battery 100 is defective.

The operation of the battery discharge curve, the calculation of the required charging time and the determination of the failure of the battery 100 will be described later.

The charging unit 400 receives the charge required time calculated from the controller 300 and charges the battery 100 with a voltage obtained by subtracting the residual voltage data from the full charge voltage during the charge required time through a predetermined charging circuit.

2 is a flowchart illustrating an operation of a battery charging method according to the present invention.

3 is a graph of a battery discharge curve generated according to an embodiment of the battery charging method of the present invention, X axis represents the passage of time and Y axis represents the discharge voltage of the battery.

The operation of the battery charging method of the battery charging apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3 as follows.

First, the controller 300 calculates a discharge voltage equation over time using a battery discharge curve (S100). Since the battery discharge curve is different depending on the capacity, characteristics, and manufacturer of the battery 100, the corresponding battery discharge curve can be obtained from a battery manufacturer or through repeated experiments.

In this embodiment, the voltage equation room with the lapse of time Y = 1E-11X ³ - will be explained with an example that the 5E-08X yield as a ² + 3E-05X + 4.125. Here, Y represents the discharge voltage of the battery and X represents the passage of time.

When the battery 100 is self-discharged while not in use, the voltage detector 200 detects a current voltage of the battery 100 and outputs residual voltage data (S200).

The controller 300 receives residual voltage data from the battery 100 and compares the residual voltage data with a predetermined full charge voltage to determine whether the residual voltage data is less than the full charge voltage (S300).

If the residual voltage data is less than the full charge voltage, the controller 300 determines that the battery 100 is in a insufficient charge state, and calculates the required charging time t1 from the discharge voltage calculation formula, and the residual voltage data is the full charge voltage. In this case, the battery 100 is determined to be in a fully charged state and the operation of the battery charging device is terminated.

For example, if the preset full charge voltage is 3.8V and the current residual voltage data of the battery 100 detected by the voltage detector 200 is 3.7V, the controller 300 indicates that the battery 100 is in a state of insufficient charging. In operation S400, the charging required time t1 is calculated from the discharge voltage equation. That is, as shown in Figure 3, it can be calculated that 10 minutes is required to charge 0.1V in the discharge voltage equation.

If the current residual voltage data of the battery 100 detected by the voltage sensing unit 200 is 3.9 V, the controller 300 determines that the battery 100 is in a fully charged state, and thus no longer needs to be charged, thereby charging the battery. Terminate the operation of the device.

The charging unit 400 receives 10-minute data, which is the time required for charging (t1) calculated from the control unit 300, through the built-in charging circuit for 10 minutes, and the current remaining voltage data of the battery 100 at the full charge voltage of 3.8V. Only 0.1V minus 3.7V is charged to the battery 100 (S500).

After the counter 500 increases the number of charges of the battery 100 by "1" (S600) and outputs the number of charges, the control unit 300 receives the number of charges from the counter 500 and determines whether or not it is N or more ( S700). Here, the number of charges starts from "0".

If it is determined that the number of charges of the battery 100 is greater than or equal to N, the controller 300 determines that the battery 100 is defective, and if the number of charges of the battery 100 is determined to be less than N, the residual voltage The data is fed back to the step of comparing the data with the predetermined full charge voltage (S300) and the subsequent operation is repeated. Here, N is preferably set to 4 to 6 times, more preferably 5 times.

For example, if it is assumed that the number of charges is three times, the control unit 300 returns to step S300 and repeats the subsequent operation, but when the number of charges reaches five times, it is determined that the battery 100 is defective ( S800) the operation of the battery charging device is terminated.

As described above, the battery charging method according to the present invention calculates a discharge voltage equation using a battery discharge curve, calculates a charging time using the same, and performs a full discharge by charging only the required voltage at the calculated time without a full discharge. As the process of charging in the form of semi-charging again, the time required for charging the rechargeable battery can be minimized without the additional time and the need for additional work.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

100: battery
200: voltage detection unit
300:
400: charging unit
500: counter

Claims (7)

(a) calculating a discharge voltage equation using a discharge curve of the battery;
(b) sensing the voltage of the battery and outputting residual voltage data;
(c) calculating a charging time required from the discharge voltage equation when the residual voltage data is less than a predetermined full charge voltage;
(d) charging the battery for the charging time required;
Battery charging method comprising a.
The method of claim 1,
After step (d)
(e) increasing the number of charges of the battery by one;
(f) receiving the number of charges and determining that the battery is defective when N or more;
Battery charging method comprising a further.
The method of claim 2,
N is
Battery charging method characterized in that 4 to 6 times.
The method of claim 2,
N is
Battery charging method characterized in that five times.
The method of claim 1,
The step (d)
And charging the battery with a voltage obtained by subtracting the residual voltage data from the full charge voltage.
The method of claim 1,
The discharge curve of the battery is
Battery charging method characterized in that obtained from a battery manufacturer or obtained through repeated experiments.
A voltage detector configured to detect a current voltage of the battery and output residual voltage data;
A counter for counting and outputting the number of charges of the battery;
Calculate the discharge voltage calculation formula from the battery discharge curve, calculate the required charging time from the discharge voltage calculation formula by receiving the residual voltage data and compare it with a preset full charge voltage, and whether the battery is defective by receiving the charge count. A control unit for determining;
A charging unit configured to receive the charging time and charge the battery for the charging time;
Battery charging apparatus comprising a.

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