KR101158936B1 - Battery Managing Method and Potable Terminal Equipment with the same - Google Patents

Abstract

The present invention relates to a battery management method and a portable terminal device using the same. In the present invention, when the microprocessor 50 supplies the charging power VC of the battery 30 to the power supply target 60, the microprocessor 50 detects the charging current of the battery 30 and discharges a battery having a large charging current first. . In addition, when the AC-DC adapter 70 is connected and the power supply VS is input, the microprocessor 50 first charges a battery having a large charging current. Accordingly, the present invention can shorten the charging time by first discharging and charging a battery having a large charge current detected through the detector 40.

Battery, charging circuit, charging current, charging time, portable terminal device

Description

Battery management method and portable terminal device using same {Battery Managing Method and Potable Terminal Equipment with the same}

1 is a diagram illustrating a portable computer equipped with a battery according to an embodiment of the present invention.

2 is a block diagram of a portable terminal device using a battery management method according to an embodiment of the present invention.

3 is a flowchart illustrating a battery management method of FIG. 2 step by step.

4 is a battery characteristic table illustrating battery information.

`` Explanation of symbols for main parts of drawings ''

10: path control circuit 20: charging circuit

30: battery 30a: main battery

30b: optional battery 40: detector

50: microprocessor 65: ODD

70: AC-DC adapter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable terminal device, and more particularly, to a battery management method for determining a discharge and charging rank according to a charging current of a battery, and a portable terminal device using the same.

The biggest feature of the portable terminal device is mobility. Accordingly, when a commercial AC power source cannot be used, dual batteries are employed to increase the use time of the portable terminal device. In this case, a battery mounted inside the portable terminal device is called a main battery, and a battery mounted on a space where an optical disk drive (ODD) is detached or an exterior of the main battery is called an optional battery.

Generally, a portable terminal adopting a battery uses an option battery among batteries when the system is discharged to drive the system. Thus, when the option battery is fully discharged, the system is driven using the primary battery.

In addition, in the case of charging the battery, the portable terminal adopting the general battery first charges the main battery and then the optional battery. This is because the option battery is mounted in an external form, so that the option battery is discharged first and then charged later in consideration of the case where the option battery is detached.

In general, the battery charging time of the portable terminal device is proportional to the battery usage rate. For example, if a battery having a small battery capacity and a battery having a large battery capacity are used for the same time and then charged, the charging time of the small battery takes longer than that of the large battery. This is because the portable battery is charged by adjusting the charging current according to the capacity of the battery in order to prevent damage or shorten the life of the battery. Accordingly, when the capacity of the basic battery is larger than the option battery, the conventional portable terminal discharges the option battery first regardless of the battery capacity, so that charging time is longer than that of the case where the battery having the large battery capacity is first discharged and charged. . In addition, when the capacity of the basic battery is smaller than the capacity of the optional battery, the conventional portable terminal charges the basic battery with a small battery capacity first, so the charging time is the same, but the charging effect than when charging a battery with a large charging capacity first Appears late.

As such, the portable terminal adopting the conventional battery has a problem in that the charging time is long or the charging effect is delayed even when the same time is determined by determining the charging order according to whether the main battery or the optional battery is independent of the charging current.

Accordingly, an object of the present invention is to provide a battery management method for detecting a charging current according to a battery capacity to discharge and charge a battery having a large charging current first, and a portable terminal device using the same.

Disclosure of Invention An object of the present invention is to provide a battery management method and a portable terminal device using the same, which shorten the charging time by determining the discharge and charge order according to the charging current.

Battery management method according to an embodiment of the present invention for achieving the above object is to detect the charging current for at least two batteries, the detection according to whether the supply power from the outside and the charge / discharge state of the battery Characterized in that it comprises a step of discharging and charging first, the battery with the highest charging current.

In the charging step, when the charging of the battery having the largest charging current is completed, it is preferable to charge the remaining battery.

In the discharging step, when the discharge of the battery having the largest charging current is completed, the remaining battery is preferably discharged.

Battery management method according to an embodiment of the present invention for achieving the above object is two or more batteries, a detector for detecting the charging current and the charging state of the batteries, a charging circuit for supplying charging power to the batteries, and And a controller for comparing the detected charging current to control charging through a charging circuit and discharging according to system driving from a battery having a large charging current.

The present invention may further include a path control circuit for providing a different path to provide the supply power as the charging power or the driving power, or to provide the charging power of the battery as the driving power depending on whether the supply power is supplied from the outside. It is desirable to be.

The controller may control the remaining battery to be discharged or charged when the battery having the largest charging current is discharged or charged.

By the above-described configuration, the battery management method and the portable terminal using the same according to the present invention detects the charging current of each of the batteries, and charges and discharges from the battery with a large detected charging current.

Hereinafter, a battery management method and a portable terminal device using the same will be described in detail with reference to the accompanying drawings.

1 is a view showing the bottom of the portable computer employing two or more batteries according to an embodiment of the present invention, Figure 2 is a block diagram of a portable terminal device using the battery management method of FIG.

As shown, although the option battery 30b is illustrated as being mounted outside the main battery 30a, it should be noted that the ODD 65 may be mounted in a separate space.

 A portable computer using a battery management method according to an exemplary embodiment of the present invention includes a microprocessor 50 that receives power and manages power of the entire system. The microprocessor 50 controls the battery 30 to charge the input supply power VS when the AC-DC adapter 70 is connected and the supply power VS is input from the outside. When the AC-DC adapter 70 is not connected, the system is controlled to be driven by using the charging power VC charged in the battery 30. In this case, the devices of the system driven by receiving the supply power or the charge power are referred to as the power supply target 60. In addition, the microprocessor 50 controls devices such as a keyboard and a mouse, a disk drive, and an expansion module (not shown).

The battery 30 is composed of a basic battery 30a that is manufactured to be mounted inside a portable computer and an optional battery 30b that is mounted in an external or separate space of the ODD 65. The primary battery 30a is mounted in a space provided to be inserted into the portable terminal device. In addition, the option battery 30b is mounted together with the main battery 30a and used to increase the battery usage time. In addition, the option battery 30b may be mounted on the bottom of the base battery 30a mounted on the bottom of the portable terminal device to perform an additional function of maintaining inclination when using the portable terminal device.

The basic battery 30a and the option battery 30b are configured of a battery cell array (not shown) in which one or more battery cells are arranged in series and in parallel, and a protection circuit (not shown) to protect the battery cells.

The battery 30 is charged by the charging circuit 20.

The charging circuit 20 performs a function of supplying the supply power VS to the battery 30 to charge or transferring the power VC charged in the battery 30 to the power supply target 60.

In addition, the detector 40 is provided to perform such a charging operation. The detector 40 detects the charging current and the charging state of the battery 30 and transmits the detected current to the microprocessor 50. In this case, the microprocessor 50 controls the charging circuit 20 to discharge and charge a battery having a large charging current by comparing the charging current detected by the detector 40. Accordingly, the charging circuit 20 supplies the charging current to the battery 30 by adjusting the charging current under the control of the microprocessor 50.

In addition, a path control circuit 10 for controlling the transfer path of the supply power supply VS and the charge power supply VC is provided. The path control circuit 10 supplies the supply power VS input from the AC-DC adapter 70 to the power supply target 60 and charges the battery 30 under the control of the microprocessor 50. Supply to the charging circuit 20 side. On the other hand, when the AC-DC adapter 70 is not connected, the charging power VC from the battery 30 is supplied to the power supply target 60 to drive the system.

 Hereinafter, a battery management method of a portable terminal device according to an embodiment of the present invention having the configuration as described above will be described in detail.

3 is a flowchart illustrating a step-by-step method of battery management of a portable terminal device according to an embodiment of the present invention. This is done by the microprocessor 50 of FIG.

When the power button (not shown) is operated in the tenth step S10 of FIG. 3, the microprocessor 50 checks whether the AC-DC adapter 70 is connected to input the supply power VS. When the AC-DC adapter 70 is not connected and the supply power VS is not input, in operation 20, the microprocessor 50 discharges the charging power VC of the battery 30 to supply power. The driving power is controlled to be input to the target 60, and the state of charge of the battery 30 is detected through the detection unit. In operation 22, the microprocessor 50 determines whether all of the batteries 30 are fully discharged based on the detected state of charge. At this time, when all of the batteries 30 are fully discharged, the microprocessor 50 displays a message indicating a power shortage and stops driving the system by turning off the power. Meanwhile, when one or two batteries 30 are discharged because the charging power VC remains, the microprocessor 50 detects the charging current of the dischargeable battery (S24).

When both batteries 30 are discharged, the microprocessor 50 discharges a battery having a large detected charging current and supplies driving power VS to a power supply target in operation S26. Subsequently, when the battery having the large charging current is completely discharged, the remaining battery is discharged. In this case, when there are two or more remaining batteries, it is preferable to discharge the battery by comparing the charging currents of the remaining batteries to determine the priority from the battery having the larger charging current.

On the other hand, when one battery is discharged, the corresponding battery is discharged to supply driving power to the power supply target 60.

For example, FIG. 4 is a battery characteristic table illustrating battery information. In FIG. 4, the primary battery 30a and the optional battery 30b each have a capacity of 2000 mA and a charge current of 100 mA per cell. In addition, the base battery 30a includes six cells, and the option battery 30b includes three cells. In this case, the charging current of the basic battery 30a is 600 mA, and the charging current of the option battery 30b is 300 mA. Accordingly, the microprocessor 50 discharges the primary battery 30a having a large charge current first, and later discharges the option battery 30b having a small charge current.

Through the above process, the embodiment of the present invention discharges a battery having a large charging current first when driving a power supply target by discharging the charging power of the battery.

When the supply power VS is input in the tenth step S10, the microprocessor 50 controls the path control circuit 10 to control the supply power VS in the twelfth step S12. ) And at the same time detect the state of charge of the battery 30 using the charging circuit (20). Accordingly, the microprocessor 50 determines whether all of the batteries 30 are fully charged based on the detected state of charge (S14). At this time, when all of the batteries 30 are in a fully charged state, the AC-DC adapter 70 checks whether the connection is made and waits.

Meanwhile, when one or two batteries 30 need to be charged, the microprocessor 50 detects the charging current of the battery 30 using the detector (S16). Subsequently, in step 18, the microprocessor 50 charges the corresponding battery 30 when the battery 30 needs to be charged and detects when both batteries 30 need charging. The battery with a large charging current is charged first. Subsequently, the microprocessor 50 performs the fourteenth step S14 to the eighteenth step S18 to charge the remaining battery. In this case, when the remaining batteries are two or more, the charging currents of the remaining batteries are compared and the priority is determined from the batteries having the larger charging current.

Referring to FIG. 4, when the main battery 30a and the option battery 30b use the same 3000 mA, the remaining ratio of the main battery 30a is 75%, and the remaining ratio of the option battery 30b is 50%. do. Thus, since the time required for charging is proportional to the usage ratio of the battery, the charging time of the option battery 30b having a small residual ratio takes longer. In an embodiment of the present invention, the primary battery 30a having a large charging current is discharged first, and the charging time is shortened by charging it first.

Through the above process, in the embodiment of the present invention, when the AC-DC adapter is connected and the supply power is input, the battery first charges a battery having a large charging current by detecting a charging state and a charging current of the batteries.

In the above embodiment, the case where the main battery has a larger capacity than the option battery is used, but the same applies to the case where the option battery has a larger capacity than the main battery. At this time, the option battery with a large capacity is discharged and charged first, resulting in a faster charging effect than the conventional portable terminal device.

Although the portable computer has been described in the above embodiment, the present invention can be applied to various types of portable terminal devices such as a portable communication device, a portable sound device, and a portable game machine.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and a person of ordinary skill in the art without departing from the spirit and scope of the present invention. It will be apparent that various modifications, changes, and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the battery management method and the portable terminal using the same according to an embodiment of the present invention detects the charging current of the batteries to discharge and charge the battery having a large charging current first. Accordingly, the present invention can shorten the charging time of the battery provided with two or more.

Claims (6)

Detecting charge currents for at least two batteries; And discharging and charging first of the battery having the largest detected charging current according to whether the supply power is supplied from the outside and the charging / discharging state of the battery. The charging step, When the charging of the battery with the largest charging current is completed, the remaining battery is charged, The discharge step, And discharging the remaining batteries when the discharge of the battery having the largest charging current is completed. delete delete delete delete delete

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