KR100775699B1 - Battery charging apparatus of the mobile communication terminal and the method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery charging device, wherein a battery charging of a mobile communication terminal enables charging of a discharged battery of an external mobile communication terminal by boosting the output power of a battery in a mobile communication terminal and supplying the power to an external mobile communication terminal. An apparatus and a method thereof are provided.

Battery charging device of a mobile communication terminal of the present invention for achieving the above object is a power boosting unit for receiving the output power of the residual amount from the battery of the mobile communication terminal to boost the output; A boosting power control unit for inputting a square wave control signal to the power boosting unit for controlling the voltage of the output power of the power boosting unit to a predetermined value; And a power output unit configured to output the boosted output power of the power boosting unit to an external mobile communication terminal.

Mobile communication terminal, battery charger, booster power, battery charging method

Description

Battery charging apparatus for mobile communication terminal and method thereof

1 is a block diagram of a battery charging device of a conventional mobile communication terminal,

2 is a block diagram of a battery charging device of a mobile communication terminal according to the present invention;

3 is a view showing an embodiment of a battery charging device of a mobile communication terminal of the present invention;

4 is a flowchart illustrating a process of a battery charging method of a mobile communication terminal according to an embodiment of the present invention.

* Description of Major Symbols in Drawings *

10: power input unit 20: rectifier

30: charge detection unit 40: charging unit

100: battery charger

110: boost power control unit

120: power boosting unit

121: coil 122: FET

123: diode 124: capacitor

130: power output unit

131: USB interface 132: data cable

200: battery 201: battery terminal

300: external mobile communication terminal

301: Receptacle 310: External Battery

BACKGROUND OF THE INVENTION 1. Field of the Invention A battery charging device for a communication terminal and a method thereof are provided.

1 is a view showing the configuration of a battery charging device of a mobile communication terminal in the prior art.

As shown in FIG. 1, the battery charger of the related art includes a power input unit 10 receiving external power and a rectifying unit 20 for converting and outputting AC power input from a power input unit into DC power and a rechargeable battery to be charged. It is composed of a charging unit 40 and a charging detecting unit 30 to detect the charge of the charging unit 40 is mounted with an LED light.

The charging function of the charging device of the related art having the above-described configuration is as follows.

The external AC power for charging is input to the power terminal 11 of the power input unit 10 is applied to the rectifier 20 through the diode (D1). The AC power applied to the rectifier 20 is converted to DC power by the rectifier 21, and then ripples of DC power are removed by capacitors C1 and C2 to output a stable DC power. The DC power output from the rectifier 20 is supplied to the charging terminal 40 to charge the rechargeable battery mounted on the charging terminal 40. In this process, the DC power is supplied to the charging terminal 40 to the charging sensing unit 30, and a voltage is applied by the resistor R3 configured at the base terminal of the transistor Tr1 of the charging sensing unit 30. The transistor Tr1 is turned on. When the transistor is turned on, a DC current flows from the collector terminal to the emitter terminal, indicating that the LED LED1 provided on the emitter terminal side of the transistor Tr1 is being charged by the DC current. .

However, the above-mentioned conventional charging device is generally composed of an adapter and a charger, which is inconvenient to carry. Therefore, the user may not recharge the battery at any time when the battery of the mobile communication terminal is discharged.

In addition, a data cable or a charger for a vehicle having a 24 pin connector and a USB port for supplying power is provided in order to alleviate the inconvenience of carrying such a portable cable. However, the data cable is also provided with a power supply provided from a USB port of an external computer. Alternatively, since the vehicle is operated by a cigar jack power of the vehicle, there is a problem in that the battery cannot be charged in a place without the power.

Accordingly, the present invention is to solve the above-mentioned problems of the prior art, by boosting the output power of the battery having the remaining amount of charging power to supply the discharged battery of the external mobile communication terminal by supplying the battery to the discharged external mobile communication terminal It is an object of the present invention to provide a battery charging device and a method thereof of a mobile communication terminal capable of charging.

Battery charging device of a mobile communication terminal of the present invention for achieving the above object is a power boosting unit for receiving the output power of the residual amount from the battery of the mobile communication terminal to boost the output; And a power output unit configured to output the boosted output power of the power boosting unit to an external mobile communication terminal.

Another embodiment of the present invention provides a battery charging device for a mobile communication terminal, comprising: a power booster configured to receive and output a residual amount of output power from a battery of a mobile communication terminal; A boosting power control unit for inputting a square wave control signal for adjusting a square wave controlling the voltage value of the boosting power source after receiving the output power of the power boosting unit; And a power output unit configured to output the boosted output power of the power boosting unit to an external mobile communication terminal.

The power booster may include: a coil configured to generate an induced current by receiving the output power of the battery; A diode provided at the output terminal of the coil to rectify the output current; A capacitor connected in parallel with the power output unit at a cathode side of the diode and having one end grounded; And a switch provided at an output terminal of the coil and switched according to a square wave control signal of the boost power control unit to boost the voltage of the induced electromotive force of the coil.

The switch has a drain connected between an output terminal of the coil and an anode side of the diode, a square wave control signal of the boost power supply controller is input to a gate, and the source is a field effect transistor (FET) that is grounded. It features.

The power output unit includes a receptacle for outputting the rectified power output from the diode and the capacitor; And a data cable having both ends of a connector coupled to the receptacle to receive power from the receptacle and to input the receptacle to an external terminal.

The boosted power controller is a CPU for controlling the mobile communication terminal.

The battery charging method of the mobile communication terminal of the present invention for achieving the above object of the present invention, the mobile communication terminal, power supply step of receiving the output power of the remaining power from the battery of the mobile communication terminal; A power rectification process of rectifying the power output in the power boosting process and removing ripple; A square wave adjustment process of adjusting a square wave controlling the boosted voltage of the rectified power to have an appropriate value after receiving the rectified power output in the power rectification process; And a power output process for boosting the output power of the battery to an appropriate voltage by the square wave output in the square wave control process and outputting the rectified power by the smoothing process.

The power boosting step includes: an induced electromotive force generation step of generating an induced electromotive force by passing the battery output power through a coil; And a step of boosting the induced electromotive force by applying a square wave to the switch connected to the coil.

The square wave adjustment process includes: an output power detection process of detecting an output power of the power output process; A square wave period adjusting step of outputting a square wave period adjusting signal by comparing a voltage value of the output power detected in the output power detecting step with a preset voltage value; The square wave period control signal output from the square wave period adjusting step includes an output power square wave adjusting step of adjusting a square wave of the output power of the voltage boosting step.

Hereinafter, with reference to the accompanying drawings showing an embodiment of the present invention will be described the present invention in more detail.

2 is a view showing the configuration of a battery charging device 100 of a mobile communication terminal of the present invention.

As shown in Figure 2, the battery charging device 100 of the mobile communication terminal of the present invention is powered from the battery 200 to the main circuit (main circuit) of the mobile communication terminal in the mobile communication terminal equipped with the battery 200 Is connected in parallel to the terminal for supplying the power is supplied from the battery, it is configured to boost the power supplied to output to an external mobile communication terminal.

The above-described battery charger 100 is output from the power boosting unit 120 for boosting the output power of the battery 200 and the power output unit 130 and the power output unit 130 for outputting the boosted power. The booster power control unit 110 detects power and outputs a boosted power control signal for controlling the boosted power of the power booster 120 to the power booster 120.

Here, the boosted power controller 110 detects the voltage of the output power of the function control and the power output unit of the mobile communication terminal, compares it with the output voltage of the power booster 120, and changes the period of the square wave according to the voltage difference. As a result, the square wave clock is outputted to the power booster 120 to output the power boosted to have a predetermined voltage value.

Accordingly, the power booster 120 boosts the output power of the battery to an appropriate voltage according to the square wave control signal (square wave clock) and outputs the voltage. The boosted power boosted by the power booster 120 is output to the external mobile communication terminal 300 through the receptacle 301 of the external mobile communication terminal 300 using the data cable 132 having a connector. The discharged battery 310 is charged.

The boosting power control unit 110 configured in the battery charging device 100 of the present invention for driving the battery charging function as described above may allow the user to control the charging function for charging the battery of the external mobile communication terminal. Provides a user interface.

3 is a block diagram of a mobile communication terminal having a battery charging device 100 according to an embodiment of the present invention.

As shown in FIG. 3, the power booster 120 is provided with a coil 121 that receives power from the output terminal 201 of the battery 200 and generates induction electromotive force, and at the output terminal of the coil 121. In parallel, the diode 123 and the FET 122 as a switch are connected. Here, a cathode side of the diode 123 and a drain of the FET 122 are connected to an output terminal of the coil 121, and the FET 122 is connected to a gate in the boosted power control unit 110. The square wave control signal output terminal of the boosted power supply control unit (CPU) 110 is connected so that the output square wave control signal (square wave clock) is input, and the source is grounded.

On the anode side of the diode 123, the above-described power output unit 130 and the capacitor 124 are connected in parallel. The other end of the capacitor 124 is grounded. The capacitor 124 rectifies the voltage output from the coil 121 together with the diode 123 and performs a smoothing operation to remove ripple. Here, the diode 123 performs a rectifying action and a blocking function of reverse current.

The power input port of the boosted power control unit (CPU) 110 for detecting the boosted power is connected to the boosted power input terminal of the power output unit 130.

The power output unit 130 is provided with a USB interface 131 for supplying power to the outside or receiving external power and performing a receptacle function of a mobile communication terminal for short-range data communication with the outside, and a USB interface 131. ) Is configured such that the data cable 132 having a connector at both ends is coupled to an external mobile communication terminal and a receptacle.

4 is a flowchart illustrating an operation process of the battery charging apparatus 100 in the mobile communication terminal of FIG. 3 and a processing procedure according to an embodiment of the battery charging method of the mobile communication terminal of the present invention.

Hereinafter, an operation process of the battery charger 100 of FIG. 3 and a process of the battery charging method of the present invention will be described with reference to FIGS. 3 to 4.

First, the user sets an external charging function to externally output the boosted power for charging through a user interface provided by a boosted power control unit (CPU) 110 of a mobile communication terminal equipped with a battery having residual power. . The power of the battery 200 is input through the coil 121 by setting the external charging function, and the booster power controller 110 boosts the power of a square wave control signal (square wave clock) to boost the power to the set voltage of the software. The boosted power is generated by performing switching on the induced electromotive force of the coil by inputting the gate of the FET 122 configured in the unit 120 (S10).

Referring to the process of boosting the induced electromotive force of the coil by the above-described S10 process as follows.

When power of the battery 200 is supplied to the coil 121, induction electromotive force is generated by the coil 121. When the square wave control signal output from the boosted power control unit (CPU) is input to the gate of the FET 122, the FET 122 is switched to change the period of the square wave, thereby reacting with the induced electromotive force of the coil 121 to boost the voltage. Generate power. In more detail, when the voltage of the gate of the FET 122 causes a certain voltage difference with the source, the drain and the source are connected, and the voltage between the gate and the source. If the difference is 0V, drain and source are disconnected. That is, the FET 122 is turned on or off depending on the high and low states of the square wave (frequency) input to the gate. The period of the square wave (frequency) is several tens to hundreds of KHz. At this time, while the FET 122 is turned on, when the voltage increases to the coil 121 and the switch is turned off, the voltage applied to the coil 121 increases and decreases momentarily, and the value at the moment when the first FET 122 is turned on. In this case, the FET 122 is turned on again to start a new cycle. In this process, if the FET 122 is turned on early and the current does not reach the current when the first 'cycle' starts, but one cycle ends and a new 'cycle' starts, the cycle starts again at a higher current and continues. As the FET 122 is turned off, more current flows into the capacitor 124 and the load. In this way, the switching cycle of the FET 122 is repeated by the square wave (frequency), so that it is possible to output a desired voltage at a higher output voltage. At this time, the boosted voltage should be adjusted to be generated several volts higher than the discharged portable terminal. If the voltage is too high, there is a risk of heat generation, and if the boosted voltage is too low, it takes a long time to charge.

Next, the diode 123 and the capacitor 124 perform rectification and ripple removal of the boost power to perform a power rectification process to stabilize the boost power (S20).

The boosted power stabilized by the step S20 is detected by the boosted power controller 110 and then compared with a preset voltage value. As a result of the comparison, if the voltage value of the boosted power supply is low, the period of the square wave is increased, and if the voltage value of the boosted power supply is higher than the preset voltage value, the period of the square wave is slowed and input to the gate of the FET 122 to input the voltage of the boosted power supply. The square wave control process is performed to match the value to the preset voltage. Here, the reason for changing the square wave to adjust the voltage is because the voltage rises when the period of the square wave (frequency) is short, and the voltage drops when the period is long (S30).

The boosted power boosted to the preset voltage value by the above-described S30 process is again rectified and stabilized by the diode 122 and the capacitor 123, and then the power output unit 130 for charging the battery mounted in the external mobile communication terminal. It is supplied to the external mobile communication terminal through the USB interface 131 and the data cable 132 of (S40).

The present invention described above allows charging of a discharged battery of a mobile communication terminal from another user's mobile communication terminal even when external power cannot be supplied.

Therefore, when there is an important reception or significant business during discharge of the battery to charge by using the other user's mobile communication terminal provides an effect that can easily cope with an emergency situation.

In addition, it provides convenience in use that does not require carrying the charger at all times for emergency charging when the battery is discharged.

Claims (9)

A power booster configured to generate an induced electromotive force by receiving a residual amount of output power from a battery of a mobile communication terminal and to boost the induced electromotive force by switching a switch provided at an output terminal of the coil to output a boosted power; And a power output unit configured to receive the boosted power and output the boosted power to an external mobile communication terminal through a data cable. A power booster configured to generate an induction electromotive force by receiving a residual amount of output power from a battery of a mobile communication terminal, and boost the induction electromotive force by switching a switch provided at an output terminal of the coil to output an output power; A boosted power controller configured to input a square wave control signal for controlling switching of the switch to the power booster to control a voltage value of the output power of the power booster; And a power output unit receiving output power from the power boosting unit and outputting the output power to an external mobile communication terminal through a data cable. The method of claim 2, wherein the power boost unit, A diode provided at an output end of the coil to rectify the output current of the coil; And A capacitor connected in parallel with the power output at the cathode side of the diode and grounded at one end to remove ripple in the output current of the coil Battery charging device of a mobile communication terminal, characterized in that it further comprises. The method of claim 3, wherein the switch, A drain is connected between an output terminal of the coil and an anode side of the diode, a square wave control signal of the boost power supply controller is input to a gate, and a source is a field effect transistor (FET) which is grounded. Battery charging device. The method of claim 3, wherein the power output unit, A receptacle for outputting rectified power output from the diode and the capacitor, The data cable includes a connector coupled to the receptacle at both ends to receive power from the receptacle and to be input into the receptacle of an external terminal. The method of claim 2, wherein the booster power control unit, Battery charging apparatus for a mobile communication terminal, characterized in that the CPU for controlling the mobile communication terminal. In the mobile communication terminal for boosting the battery output power, A power-up step of boosting the output voltage of the battery; A power rectification process of rectifying the power output in the power boosting process and removing ripples; A square wave adjustment process of adjusting a square wave controlling the boosted voltage of the rectified power to have an appropriate value after receiving the rectified power output in the power rectification process; And a power output process of boosting the output power of the battery to an appropriate voltage by the square wave output in the square wave control process and outputting the rectified power by the smoothing process. . The method of claim 7, wherein the power-up process, An induction electromotive force generating process of generating an induction electromotive force by passing the battery output power through a coil; And a boosting step of boosting the induced electromotive force of the coil by applying the square wave control signal to the switch connected to the coil. The method of claim 7, wherein the square wave control process, An output power detection process for detecting an output power in the power output process; A square wave period adjusting step of outputting a square wave period adjusting signal by comparing a voltage value of the output power detected in the output power detecting step with a preset voltage value; And a square wave period adjusting step of outputting a square wave period adjusting signal output from the square wave period adjusting step to adjust a square wave of the output power of the voltage boosting step.

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