KR100487622B1 - Device and the Method for variating the charging current of battery - Google Patents

Abstract

An object of the present invention is to provide a battery charging current variable device and method for minimizing heat generation by measuring the adapter output voltage and the battery voltage of the mobile communication terminal to vary the charging current of the battery according to the difference between the two voltages.

To this end, the present invention and the adapter voltage detection unit for detecting the output voltage of the battery charging adapter. When the voltage difference between both ends is large, the battery voltage detector detects the charge voltage of the rechargeable battery and the output voltage of the adapter detected by the adapter voltage detector and the charge voltage of the battery detected by the battery voltage detector. It consists of a constant voltage / constant current control circuit that controls the charging current to match the power distribution of the device, which prevents overheating caused by charging the battery of the mobile communication terminal, and thus has a useful effect of preventing damage to components such as transistors. Provide.

Description

Device and the method for variating the charging current of battery}

The present invention relates to a device and a method for varying the charging current of the battery, in particular to measure the adapter output voltage and battery voltage of the mobile communication terminal to vary the charging current of the battery according to the difference between the two voltages to minimize heat generation The present invention relates to a battery charging current variable device and a method thereof.

In general, portable electronic devices use a battery as a source of power required for operation. The battery converts chemical energy of an internal active material into electrical energy by an electrochemical reaction, which plays a decisive role in the opening of the information age. Batteries are essential for all portable electronics, from toys to advanced products.

However, since the battery has a limited use time, it causes a lot of restrictions on the use of portable electronic products. Thus, the battery is classified into a primary battery that is disposed of in one use and a secondary battery that can be repeatedly recharged. The battery occupies an indispensable place in wireless communication devices such as mobile phones, mobile communication terminals, common frequency communicators, wireless data transceivers, and position measuring systems, as well as laptops and camcorders.

These portable devices require lightweight secondary batteries and continuous use for a long time. For this purpose, nickel-cadmium (Ni-Cd) batteries, nickel-hydrogen (Ni-MH) batteries, lithium-ion (Li-ion) batteries, and lithium polymers ( Li-Polymer) batteries have been developed and used. In recent years, lithium-ion (Li-ion) batteries, which have excellent characteristics in energy density, cycle life and other performances, have been commonly used.

In the case of the secondary battery as described above, if the charge and discharge are repeated, the solid solution is generated at the position where the charge and discharge are repeated, which prevents the remaining capacity from being used, that is, the memory effect of remembering the limit of the capacity of the battery. Is generated, the battery should be used after the charge to the discharge range to increase the efficiency of use of the battery.

Recently, as shown in FIG. 1, a built-in charging circuit 100 embedded in a mobile communication terminal is widely used, and an output voltage of a high AC / DC adapter 110 used in a built-in charging circuit is a lithium ion battery. (150) There is a problem that heat may be generated or damaged in the transistor TR or the field effect transistor 120 of the DC / DC converter used for charging.

The lithium ion battery 150 is charged after processing the supply voltage from the AC / DC adapter 110 through the FET 120 and the current sensing resistor 130.

In this case, the lithium ion battery 150 is charged in the form of constant voltage / constant current by the constant voltage / constant current control circuit 140. When the voltage of the battery 150 is low, the lithium ion battery 150 is charged with a constant current. Change.

Here, if the voltage of the adapter 110 is high and influences the power dissipation of the transistor or the field effect transistor FET 120, the transistor or the field effect transistor may be damaged due to overheating.

For example, if the power dissipation of the transistor is 1 watt (W), the voltage of the adapter is 6 volts, the battery voltage is 3 volts, and the charging current is 1 amp (A), the actual power dissipation of the transistor is 3 watts. By tripled, the transistor will break due to overheating.

Accordingly, the present invention has been proposed to solve the above-described problems, and by measuring the adapter output voltage and the battery voltage of the mobile communication terminal to change the charging current of the battery according to the difference between the two voltages to minimize the battery charge An object of the present invention is to provide a current variable device and a method thereof.

In accordance with an aspect of the present invention, a battery charging current variable device includes a transistor and a current detection resistor, wherein the battery charging device charges a current supplied from an external power source through a charging adapter to a battery. An adapter voltage detector for detecting an output voltage. A battery voltage detector for detecting a charge voltage of a battery charged to the battery through the transistor and a current detection resistor, an output voltage of the adapter detected by the adapter voltage detector and the battery voltage detector, and a charge voltage of the battery, respectively And a constant voltage / constant current control circuit for controlling the amount of current to be charged when the voltage difference between both ends is greater than or equal to a predetermined value by comparing the magnitude of.

The constant voltage / constant current control circuit reduces the charging current when the output voltage of the adapter detected by the adapter voltage detector is lower than the charge voltage of the battery detected by the battery voltage detector.

The constant voltage / constant current control circuit increases the charging current when the output voltage of the adapter detected by the adapter voltage detector is higher than the charge voltage of the battery detected by the battery voltage detector.

The present invention provides a method for controlling a variable charging current of a battery, the method comprising: detecting an output voltage of a charging adapter. Detecting a charging voltage charged in the battery through a transistor and a current detecting resistor, and comparing an output voltage of the adapter detected by the adapter voltage detecting unit and the battery voltage detecting unit with a magnitude of the charging voltage of the battery; Reducing the charging current if the output voltage of the adapter is lower than the charging voltage of the battery in the comparing step; and increasing the charging current if the output voltage of the adapter is higher than the charging voltage of the battery in the comparing step. It comprises the step of.

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

2 is a diagram schematically showing a general configuration of a mobile communication system to which the present invention is applied.

The mobile communication system includes mobile communication terminals 210 and 211 for transmission and reception, a plurality of base stations 220a and 220b, 220n, and a plurality of base station controllers 230a and 230b for controlling the base stations. 230n and the switching center 240.

The plurality of base stations (220a) (220b) ... 220n serves to change the signal format between the mobile communication terminal (210) (211) and the switching center 240 for transmission and reception so as to be suitable for a wireless link and a wired link. And it measures the transmit and receive field strength (radio wave reception strength) of the mobile communication terminal 210, 211 for transmission and reception and provides it to the switching center 240.

The plurality of base station controllers 230a, 230b..., 230n serve as a means for connecting the functions of each element of the plurality of base stations and cell operators, and the management of the plurality of base station operations, the management of the service state of the base station hardware and software, It performs functions such as allocating and configuring resources for call traffic, establishing information on base station operation, monitoring base station related to base station operation, monitoring and failure.

The switching center 240 provides a circuit switched service to the plurality of base station controllers 230a, 230b, 230n and the mobile communication terminals 210, 211 for transmitting and receiving and handoff the channel with an additional function. It has a function.

In such a general mobile communication system, when any terminal user makes or receives a call using the mobile communication terminals 210 and 211 for transmitting and receiving, any one of a plurality of base stations 220a, 220b, ... 220n It is connected to one base station.

3 is a block diagram of a built-in charging circuit built in a mobile communication terminal according to an embodiment of the present invention, the output voltage of the high AC / DC adapter (310) used in the built-in charging circuit 300 is lithium It is applied to the transistor TR of the DC / DC converter (Series regulator) or the field effect transistor 320 used to charge the ion battery 350 and to the adapter voltage detector 360 at the same time.

The charging of the lithium ion battery 350 is performed after the supply voltage from the AC / DC adapter 310 is processed through the transistor 320 and the current detection resistor 330.

In this case, the lithium ion battery 350 is charged in the form of constant voltage / constant current by the constant voltage / constant current control circuit 340. When the voltage of the lithium ion battery 350 is low, the lithium ion battery 350 is charged with constant current, and the voltage is about 4.2 volts. To constant voltage.

The charging voltage of the lithium ion battery 350 is detected by the battery voltage detector 370.

Here, the most problematic part is a heat generation problem of the transistor 320. The heat generation of the transistor 320 is an output voltage of the AC / DC adapter 310 and the lithium ion battery 350 as shown in FIG. 4. Occurs according to the charging current of.

As shown in FIG. 4, the output voltage of the AC / DC adapter 310 gradually increases from 5 volts to 8 volts while the charge current value and the battery voltage of the lithium ion battery 350 are constant at 0.5 amps and 4 volts, respectively. The power dissipation rises from 0.5 watts gradually to 2 watts.

When the output current of the AC / DC adapter 310 gradually increases from 5 volts to 8 volts while the charge current value and the battery voltage of the lithium ion battery 350 are constant at 0.8 amps and 3.5 volts, respectively, the power distribution value is increased. It gradually rises from 1.2 watts to 3.6 watts.

When the output current of the AC / DC adapter 310 gradually increases from 5 volts to 8 volts while the charge current value and the battery voltage of the lithium ion battery 350 are constant at 1 amp and 3 volts, respectively, the power distribution value is increased. It gradually rises from 2 watts to 5 watts.

5 is a flowchart showing the overall operation flow according to the method of varying the battery charging current according to the embodiment of the present invention. When the operation is started, the output voltage ADVOLT of the AC / DC adapter 310 is determined by the adapter voltage detection unit 360. In operation 501, the charging voltage BATVOLT of the lithium ion battery 350 is detected by the battery voltage detector 370.

The constant voltage / constant current control circuit 340 charges the output voltage of the AC / DC adapter 310 detected by the adapter voltage detector 360 and the lithium ion battery 350 detected by the battery voltage detector 370. The magnitude of the voltage is compared with each other (503), and when the voltage difference between both ends is large, the control to reduce the charging current to match the power distribution of the transistor 320 is performed.

That is, when the output voltage of the AC / DC adapter 310 detected by the adapter voltage detector 360 is low and the charge voltage of the lithium ion battery 350 detected by the battery voltage detector 370 is high, the constant voltage The constant current control circuit 340 controls to reduce the charging current 504 to match the power distribution of the transistor 320.

On the contrary, when the output voltage of the AC / DC adapter 310 detected by the adapter voltage detector 360 is high and the charge voltage of the lithium ion battery 350 detected by the battery voltage detector 370 is low, The constant voltage / constant current control circuit 340 controls to raise the charging current 505 to match the power distribution of the transistor 320.

In the present invention, the built-in charging circuit, the AC / DC adapter 310 and the lithium ion battery 350 is not only shown as an embodiment, but also applied to various external charging circuits and various adapters and batteries, the effect is the same.

As described in detail above, the present invention measures the adapter output voltage and the battery voltage of the mobile communication terminal to vary the charging current of the battery according to the difference between the two voltages, thereby minimizing heat generation, resulting in overheating generated during battery charging of the mobile communication terminal. And thus provide a useful effect to prevent damage to components such as transistors.

1 is a block diagram of a built-in charging circuit built in a conventional mobile communication terminal.

2 is a diagram schematically showing a general configuration of a mobile communication system to which the present invention is applied.

3 is a block diagram of a built-in charging circuit built in a mobile communication terminal according to an embodiment of the present invention.

4 is a display showing power distribution of a transistor according to the voltage and current of the present invention.

5 is a flowchart illustrating an overall operation flow according to a method of varying a battery charge current according to an embodiment of the present invention.

Claims (6)

In a battery charging device comprising a transistor and a current detection resistor to charge the battery with a current supplied from an external power source through a charging adapter, An adapter voltage detector for detecting an output voltage of the charging adapter; A battery voltage detector configured to detect a charging voltage of a battery charged in the battery through the transistor and the current detection resistor; Constant voltage / constant current for controlling the amount of current charged when the voltage difference between both ends is greater than a predetermined value by comparing the output voltage of the adapter detected by the adapter voltage detector and the battery voltage detector with the magnitude of the charging voltage of the battery. Battery charging current variable device including a control circuit. The apparatus of claim 1, wherein the constant voltage / constant current control circuit reduces the charging current when the output voltage of the adapter detected by the adapter voltage detector is lower than the charge voltage of the battery detected by the battery voltage detector. . The apparatus of claim 1, wherein the constant voltage / constant current control circuit increases the charging current when the output voltage of the adapter detected by the adapter voltage detector is higher than the charge voltage of the battery detected by the battery voltage detector. In the method of controlling by varying the charging current of the battery, Detecting the output voltage of the charging adapter; Detecting a charging voltage charged in the battery through a transistor and a current detection resistor; Comparing the output voltage of the adapter detected by the adapter voltage detector and the battery voltage detector with the magnitude of the charging voltage of the battery; Reducing the charging current when the output voltage of the adapter is lower than the charging voltage of the battery in the comparing step; And increasing the charging current if the output voltage of the adapter is higher than the charging voltage of the battery in the comparing step. delete delete