KR100449650B1 - Charge control method of portable charger for mobile phone - Google Patents

Abstract

The present invention can simultaneously charge the battery of the secondary battery and the mobile phone by the DC power source converted from the travel adapter, and the secondary battery when the mobile phone is not electrically connected to the receiving groove of the front housing. Discharge of the charged charging power can be prevented, and when the ambient temperature is a high temperature above a certain temperature (45 ° C. or higher) or a low temperature below a certain temperature (-5 ° C. or lower), charging can be prevented and the secondary battery The charged DC power can be easily charged to the battery of the mobile phone, and electrically connected to the hands-free kit to easily charge the battery of the mobile phone using a car battery. By connecting electrically, the travel adapter can be used to simultaneously charge the batteries of the secondary battery and the mobile phone.

Description

Charging control method of mobile charging device for mobile phone {CHARGE CONTROL METHOD OF PORTABLE CHARGER FOR MOBILE PHONE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable charging device for a mobile phone (also called a mobile communication terminal, a hand phone, or a mobile phone). The present invention is particularly portable and can easily charge a DC power charged in a secondary battery to a mobile phone battery. In addition, the present invention relates to a portable charging device of a mobile phone capable of simultaneously charging a battery of a secondary battery and a mobile phone using a travel adapter.

As a portable charging device incorporating a rechargeable battery widely used in the related art, it is disclosed in Korean Utility Model Registration No. 20-0275514 (Registration Date; May 1, 2002).

As shown in FIGS. 1 and 2, a portable charging device having a built-in rechargeable battery disclosed in Registration No. 20-0275514 of the Utility Model Registration Publication may be connected to a power plug so as to be connected to a home power outlet on one side of the main body 100. An AC power supply connecting portion 110 provided with 111 is attached.

The power plug 111 is folded at right angles through the rotation shaft 112 provided inside the main body 100 and fixed to the surface of the main body 100 at right angles when used (shown in dashed lines), and when not in use. It is configured to be seated in the insertion groove 113 formed on one side of.

In addition, at one side of the main body 100, a cable 151 and an interface jack provided at one side of the cable 151 so as to be electrically connected to an interface connector (not shown) such as a mobile phone (or a hand phone). 152 is provided, and the internal terminal of the mobile phone interface connector (not shown) is electrically connected to the positive terminal, the negative terminal, and the identification data input terminal IN of the external battery connection unit 115. .

As shown in FIG. 2, an AC power connection unit 120 is electrically connected to an AC power source of 110V or 220V, which is a home power source, and removes noise components of AC power applied through the AC power connection unit 120. Electromagnetic interference (EMI) filter 121 is connected to the AC power connection unit 120, and the AC filter 121 rectifies AC power applied through the EMI filter 121 to DC power to switch mode. The rectifier 122 is connected to supply the power supply 114.

The switching mode power supply unit 114 receives a DC power input from the rectifying unit 122 and supplies a charging current that is stepped down (dropped) according to a duty ratio, and the switching mode power supply unit 114 supplies the A coil unit 141a for generating a step-down induced current by intermittent the DC power input from the rectifying unit 122 and a switching for controlling the amount of charging current flowing into the rechargeable battery by intercepting the coil unit 141a according to the duty. It is comprised by the control part 114b.

The external battery connection unit 115 is configured to apply predetermined identification data ID transmitted from the identification terminal of the battery in the mobile phone to the microprocessor 119 through the identification data output terminal OUT. (Not shown), the interface jack 152 is positive (+) input terminal, negative (-) input terminal and identification so as to be electrically connected to the charging terminal, ground terminal and identification terminal of the battery of the mobile phone (not shown), respectively The data input terminal IN is provided.

In FIG. 2, the pulse width modulation (PWM) control unit 116 reaches a predetermined reference voltage based on a predetermined voltage control signal applied from the microprocessor 119. Adjusting the voltage level of the current charging voltage to be maintained, the modulation signal output terminal of the PWM control unit 116 is connected to the base terminal of the transistor Q1, the output terminal of the switching mode power supply 114 for reverse current blocking It is connected to the collector terminal of the transistor Q1 through the diode D1, the charging current input terminal of the external battery connection unit 115 is connected to the emitter terminal of the transistor Q1, the emitter terminal is the PWM control unit ( 116 is connected to the voltage feedback signal input terminal.

The internal battery 117 connected to the output terminal of the switching mode power supply 114 stores an internal battery (secondary battery) storing the electrical energy using a DC power output from the switching mode power supply 114 as a charging current. As an example, the internal battery 117 is a battery in which charge is charged to charge an external battery (battery of a mobile phone) connected to the external battery connection unit 115.

The internal battery 117 includes a predetermined overcharge preventing circuit for preventing overcharge therein, and converts a predetermined current control signal applied from the microprocessor 119 into an optical signal and converts the optical signal into a predetermined duty. A photocoupler 118 is connected between the microprocessor 119 and the switching control unit 114b of the switch mode power supply unit 114 to convert an electrical signal having a ratio to interrupt the application to the switching mode power supply unit 114. It is.

In the above description, when the battery of the mobile phone is connected to the external battery connection unit 115, the microprocessor 119 reads the identification data ID of the corresponding battery transmitted from the external battery connection unit 115 to the maximum. A charging voltage and a charging current value are set and the operations of the switching mode power supply 114 and the PWM controller 116 are controlled based on the charging voltage and the charging current value.

The portable charging device with a built-in conventional rechargeable battery configured as described above is a user who wants to charge the battery of the mobile phone in a travel destination when the battery charging power of the mobile phone is used for home 110V / 220V AC power. Is inserted into a household power outlet, and the interface jack 152 is connected to an interface connector (not shown) of the mobile phone.

Next, the AC power flowing through the AC power connection unit 120 is filtered through the EMI filter 121 and after the noise component is filtered, rectified by the rectifier 122 to DC power, rectified DC power Is applied to the switching mode power supply 114.

The DC power applied to the switching mode power supply 114 is used as a charging power for charging the battery of the mobile phone and the internal battery 117 not shown under the control of the microprocessor 119.

In this case, the microprocessor 119 applies a predetermined current control signal, which is a pulse width modulation signal, to the photocoupler 118 according to a preset maximum charging voltage and maximum charging current of the internal battery 117, and then the external battery. Read the identification data (ID) of the battery of the mobile phone transmitted from the connection unit 115 to set the maximum charging voltage and the maximum charging current of the battery, and the maximum charging voltage of the battery is the reference voltage of the PWM controller 116 Set to.

The photocoupler 118 outputs an electrical signal having a predetermined duty ratio to the switching controller 114b corresponding to the current control signal transmitted from the microprocessor 119, and the switching controller 142b outputs the electrical signal. The amount of charging current supplied to the internal battery 117 is controlled by intermittent operation of the coil unit 114a according to the duty ratio of the controller.

Meanwhile, the PWM controller 116 compares the voltage applied to the emitter terminal of the transistor Q1 and the connection node of the external battery connection unit 115 with a predetermined reference voltage at predetermined intervals. The on / off driving period of the transistor Q1 is adjusted so that the current charging voltage reaches and maintains the set reference voltage.

When the current charging voltage reaches the reference voltage, the PWM controller 116 outputs the same to the microprocessor 119, and the microprocessor 119 from the switching mode power supply 114 is based on this. A predetermined current control signal is applied to the photocoupler 118 so that the amount of charging current output is gradually reduced.

That is, the microprocessor 119 controls the operation of the switching mode power supply unit 114 according to the preset maximum charging voltage and the maximum charging current amount of the internal battery 117, but according to the current charging voltage state of the mobile phone. The charging current output from the switching mode power supply unit 114 is adjusted to prevent overcharging of the battery connected to the external battery connection unit 115. When the internal battery 117 reaches the full state, an internal overcharge prevention circuit (not shown) built in the internal battery 117 detects the full charge state and automatically blocks the inflow of the charging current.

According to the above operation, the charging current output from the switching mode power supply unit 114 charges the internal battery 117 via the diode D1 as well as is applied to the external battery connection unit 115 to the battery of the mobile phone. Can be charged.

Next, an operation of charging the battery of the mobile phone using the charging power charged in the internal battery 117 will be described.

The internal battery 117 is in the state of being charged by the above-described operation, and when the mobile phone is to be charged in a place where it is difficult to use home AC power, the interface jack 152 of FIG. (Not shown), a part of the charging power of the internal battery 117 is supplied to the operating power through an operating power supply circuit (not shown).

At this time, the microprocessor 119 reads the identification data ID of the battery of the mobile phone transmitted from the external battery connection unit 115 to set the maximum charging voltage and the maximum charging current of the corresponding battery, and the maximum charging voltage Is set to the reference voltage of the PWM control unit 116.

In addition, the PWM controller 116 compares the current charging voltage of the battery connected to the external battery connection unit 115 with a preset reference voltage so that the current charging voltage reaches and maintains the set reference voltage. The on / off drive cycle is adjusted to charge the mobile phone's battery.

By the way, the portable charging device with the conventional built-in rechargeable battery configured as described above can charge the rechargeable battery of the mobile phone even in places where it is difficult to use home AC power or the battery power of the car, but it is inconvenient to carry and also the battery of the mobile phone To charge the cable 152 is provided with an interface jack 152 is connected to the interface connector (not shown) of the mobile phone, and the other end of the cable 152 is electrically connected to the main body 100 Since there should be, there were a number of problems, such as complicated and uncomfortable charging operation.

Accordingly, the present invention has been made to solve the various problems described above, and an object of the present invention is to carry a portable battery capable of simultaneously charging a battery of a secondary battery and a mobile phone by a DC power source converted from a travel adapter to direct current. The present invention provides a charging control method of a portable charging device for a mobile phone.

Still another object of the present invention is to provide a charging control method of a mobile charging device for a mobile phone which can prevent the discharge of the charging power charged in the secondary battery when the mobile phone is not electrically connected to the receiving groove of the front housing. It is.

Still another object of the present invention is to provide a charging control method for a mobile charging device for a mobile phone which prevents charging when the ambient temperature is a high temperature (above 45 ° C.) or a low temperature (below −5 ° C.) or above a predetermined temperature. have.

Still another object of the present invention is to provide a charging control method of a mobile charging device for a mobile phone which can easily charge a DC power charged in a secondary battery to a battery of a mobile phone.

Still another object of the present invention is to provide a charging control method of a mobile charging device for a mobile phone that can be electrically connected to a hands free kit and can be easily charged to a battery of a mobile phone using a vehicle battery.

Still another object of the present invention is to provide a charging control method of a mobile charging device for a mobile phone that can be electrically connected to a desktop charging cradle and simultaneously charge a battery of a secondary battery and a mobile phone using a travel adapter.

In order to achieve the above object, the present invention provides a travel adapter determination step of determining whether a plug of a travel adapter is connected to a power line by the microprocessor receiving a signal detected by a first charging current detection detecting means, and the travel adapter. In the determination step, when the plug of the travel adapter is connected to the power line, the battery of the mobile phone is inserted into the receiving groove formed in the front housing so that the output terminal 85 formed at the bottom of the mobile phone and the interface connector are electrically connected. A first output terminal connection discrimination step of receiving the coral detected by the output terminal to determine whether it is detected by the microprocessor; and an output connector of the mobile phone and an interface connector are electrically connected in the first output terminal connection discrimination step. The ambient temperature detection means The first lower limit temperature discrimination step for discriminating whether or not the ambient temperature detected is lower than or equal to -5 degrees Celsius and the lower temperature temperature (-5 degrees Celsius) in the first lower limit temperature discrimination step; The first upper limit temperature determination step for determining whether the detected ambient temperature is 45 ° C. or higher, and the battery and the secondary battery of the mobile phone when the temperature is not higher than the upper limit temperature (45 ° C.) in the first upper limit temperature determination step. The first charging current voltage A / D value reading step of reading out the current voltage A / D value and outputting it to the microprocessor, and the battery and the secondary of the mobile phone in the first charging current voltage A / D value reading step. A first charging current / voltage A / D value compensation step of compensating charging current / voltage A / D values of the mobile phone and the secondary battery after reading the current voltage A / D values of the battery, respectively; The mobile phone in charging current / voltage A / D value compensation step And compensating for the charge current / voltage A / D value of the secondary battery and determining whether the current of the mobile phone is less than the limit current (400 mA) by the microprocessor receiving the current flowing through the output terminal. An excess current calculation step of calculating the excess current by subtracting the mobile phone current from the mobile phone limit current if the result of the limit current determination step and the result determined by the first limit current determination step are less than the limit current; The mobile phone current is cut off after calculating the excess current in the excess current calculating step (CUT-OFF; 50 mA) a first cut-off current discrimination step of discriminating by the microprocessor that has received the first charging current detected by the first charging current detecting means, and whether the current is less than 50 mA; and the mobile phone in the first cut-off current discrimination step. When the charging current is less than the cut-off current, the first phone charging voltage determination step for determining whether the charging voltage of the mobile phone is 3.9Vdc or more, and when the phone charging voltage is 3.9Vdc or more in the first phone charging voltage determination step A first phone that outputs an off control signal to the first switch from the microprocessor to turn off the battery charge of the mobile phone and emits a dual-type LED in green to turn off the battery charge of the mobile phone The microcomputer after turning off the battery charging of the mobile phone at the end of charging step and the first phone charging end step; A total limit current calculating step of calculating a total limit current for charging the secondary battery by adding an internal total limit current (200 mA) and an extra phone charging current in a processor, and calculating a total limit current in the total limit current calculating step. And determining whether the secondary battery 210 is less than an internal total limit current by the microprocessor which has received the second charging current detected by the second charging current detecting means. And a first secondary battery cutoff current determination step of determining whether the secondary battery charge current is less than or equal to the secondary battery cutoff current (50 mA) when the secondary battery charge current is less than the internal comprehensive limit current in the determination step below the internal comprehensive limit current. And as a result of the discrimination of the first secondary battery cutoff current determination step, the secondary battery cutoff current (50 mA) In the case of the first secondary battery charge determination step of determining whether the charge voltage of the secondary battery is 3.9Vdc or more, and as a result of the determination of the first secondary battery charge determination step, the charge voltage of the secondary battery At 3.9 Vdc or more, the microprocessor outputs an off control signal to the second switch to turn off the charge of the secondary battery, and at the same time, turns off the charge of the secondary battery and turns off the light emission of the dual-type LED. Characterized in that the first secondary battery charge end step.

1 is a perspective view schematically showing a portable charging device incorporating a conventional secondary battery;

2 is a block diagram schematically illustrating a control circuit in FIG. 1;

Figure 3 is a front view schematically showing a portable charging device of a mobile phone according to an embodiment of the present invention,

Figure 4 is a view from the right in Figure 3, a side cross-sectional view showing a state in which the belt clip does not operate,

5 is a side cross-sectional view showing a state in which the belt clip is operated (opened state) in FIG.

6 is a longitudinal cross-sectional view taken along the arrow A-A line of FIG. 3 with the secondary battery and the charge control circuit removed from FIG.

Figure 7 is a rear perspective view after removing the belt clip in Figure 3,

8 is a perspective view illustrating a state in which the coupling member is separated from the fixing member of the belt clip in FIG. 7;

9 is a view illustrating a state in which the coupling member is rotated by 90 degrees clockwise or counterclockwise about the fixing member of the belt clip in the portable charging device of the mobile phone according to one embodiment of the present invention;

10 is a view for explaining the mounting of the mobile phone by electrically connecting the charging cable to the portable charging device of the mobile phone according to an embodiment of the present invention,

11 is a view for explaining a state of charging the battery of the mobile phone from the secondary battery by mounting the mobile phone in the portable charging device of the mobile phone according to an embodiment of the present invention,

12 is a view showing a state in which the rear housing for explaining the state that the release button of the portable charging device of the mobile phone according to an embodiment of the present invention is not operated,

13 is an exploded schematic view of a portable charging device for a mobile phone according to an embodiment of the present invention;

14 is a block diagram schematically showing a control unit of a portable charging device of a mobile phone according to one embodiment of the present invention;

15 is a view for explaining a state of charging by combining the portable charging device of a mobile phone according to an embodiment of the present invention to the vehicle hands-free kit,

16 is a view for explaining a state of charging by mounting the portable charging device of the mobile phone according to an embodiment of the present invention to the table charger.

17 is a flowchart illustrating a method of charging a battery and a secondary battery of a mobile phone in a portable charging device of a mobile phone according to an embodiment of the present invention;

18 is a flowchart illustrating a charging control method for charging a mobile phone with a DC power charged in a secondary battery in a portable charging device for a mobile phone according to an embodiment of the present invention;

19 is a flowchart for explaining a charging control method for charging only a secondary battery in a portable charging device for a mobile phone according to one embodiment of the present invention;

20 is a flowchart illustrating a method of compensating for phone charging current voltage A / D value in a portable charging device of a mobile phone according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: Front housing 11: Screw 12: Mobile phone

14: receiving groove 16: cutting part

20: rear housing 22: receiving groove

30: belt clip 31: coupling member

31b: Home

31d: circular protrusion 32: rotating member

32a, 32b: circular projection 32c: locking member

32d: coil spring 33: fixing member

34: movable member 35: coil spring

40: key member 41: slider

42: protrusion 43: protrusion board

50: clamper 51: tension spring

51a: shaft 52: lower operating member

53: Upper operation lever 60: Release button

62: coil spring 64: slope

70: interface connector 71: block

71a: shaft 71b: coil spring

80: charge control unit 81: microprocessor

82: voltage converting means 83: first charging current / voltage detecting means

84: first constant current / constant voltage adjusting means 85: output terminal

86: first switch 87: second charging current / voltage detection means

88: second constant current / constant voltage adjusting means 89: second switch

90: discharge prevention means 91: charge state display means

92: temperature detection means 93 reference voltage setting means

94: A / D value VDD absolute value compensation means 200: adapter

202: code 204: wiring

206: wiring 208: connector

210: secondary battery 1000: portable charging device

Hereinafter, a portable charging device for a mobile phone according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a front view schematically showing a portable charging device 1000 of a mobile phone according to an embodiment of the present invention, Figure 4 is a view from the right in Figure 3, showing a state in which the belt clip does not operate FIG. 5 is a side cross-sectional view illustrating a state in which the belt clip is operated (opened state) in FIG. 4, and FIG. 6 is a line AA of FIG. 3 in a state in which the secondary battery and the charging control circuit are removed in FIG. 3. 7 is a rear perspective view of the belt clip after removing the belt clip from FIG. 3, FIG. 8 is a perspective view illustrating a state in which the coupling member is separated from the fixing member of the belt clip in FIG. 7, and FIG. In the portable charging device for a mobile phone according to an embodiment of the present invention is a view illustrating a state in which the coupling member is rotated by 90 degrees clockwise or counterclockwise around the fixing member of the belt clip, FIG. 1. 0 is a view for explaining the mounting of the mobile phone by electrically connecting the charging cable to the portable charging device of the mobile phone according to an embodiment of the present invention, Figure 11 is a portable phone of the mobile phone according to an embodiment of the present invention FIG. 12 is a view illustrating a state of charging a battery of a mobile phone from a secondary battery by mounting a mobile phone in a charging device, and FIG. 12 is a release button of a portable charging device of a mobile phone according to an embodiment of the present invention. FIG. 13 is a view illustrating a state in which a rear housing explaining a state is removed, and FIG. 13 is an exploded schematic view of a portable charging device for a mobile phone according to an embodiment of the present invention, and FIG. 14 is an embodiment of the present invention. The block diagram schematically shows a control unit of a portable charging device of a mobile phone according to an example.

2 to 14, the portable charging device for a mobile phone according to an embodiment of the present invention, the receiving groove 14 for receiving the mobile phone 12 is formed on the front, the receiving groove 14 The mobile phone 12 mounted on the mobile phone 12 can be easily gripped, and at the same time, the left and right upper portions of the receiving groove 14 can be operated to operate the volume keys (not shown) of the mobile phone 12. The front housing 10 having the formed cutting part 16 and the rear housing 20 fixedly coupled to the rear surface of the front housing 10 by a screw 11 to cover the rear opening of the front housing 10. And a belt clip 30 detachably installed in the elongated receiving groove 22 formed on the rear surface of the rear housing 20 to change the mounting position of the front and rear housings 10 and 20, and the rear housing. The bell disposed in the elongate receiving groove 22 formed on the back of the (20) The lock member 40 which prevents the clip 30 from being separated and the left and right side walls of the receiving groove 14 formed in the front housing 10 are installed in a lineable manner, respectively, on the left and right side walls of the mobile phone 12. A pair of clampers 50 which are inserted into the formed grooves and regulate the detachment of the mobile phone 12 during charging, and are installed on the upper portion between the front housing 10 and the rear housing 20 and the clampers 50. Block rotatable via a release button (60) for regulating the ingress (entry in and out) of the &lt; RTI ID = 0.0 &gt;) &lt; / RTI &gt; DC voltage converted by the interface connector 70 installed in the 71, the secondary battery 210 disposed in the space formed by the front housing 10 and the rear housing 20, and the travel adapter 200. Received through the cord 202 and the connector 208 to the secondary battery 210 and While controlling to charge the battery (not shown) of the mobile phone 12 at the same time, and controls to charge the battery of the mobile phone 12 to the DC voltage charged in the secondary battery 210 The charging control unit 80 is configured.

The belt clip 30 has a pair of protrusions 31a and 31a formed at an upper portion thereof, and grooves 31b and 31b for inserting the protrusions 42 of the lock member 40 are formed at a lower portion thereof, respectively. Coupling member 31 is inserted into the elongated receiving groove 22 formed on the rear surface of the rear housing 20 and fixed by the lock member 40 and formed in the circular projection (31d) of the coupling member 31 The circular protrusions 32a and 32b respectively inserted into the pair of grooves 31b and 31b are integrally formed, and at the same time, the locking member 32c and the coil spring 32d which bias the locking member 32c downward are formed. Fixed to receive the rotating plate 32 and the rotating plate 32 integrally coupled to the circular projection (31d) of the coupling member 31 by ultrasonic welding in a clockwise or counterclockwise direction, respectively. A member 33, a movable member 34 provided on the fixing member 33 so as to be pivotable about a hinge pin 33a, and the movable member It consists of a coil spring 35 for biasing the plate to each key in the lower portion of the material 34 the fixing member 33, the leading end (lower in Fig. 6).

The lock member 40 is formed integrally with the slider 41 which is urged upward by a spring (not shown) as shown in FIG. Protrusions 42 inserted into the grooves 31b formed below the coupling member 31 to prevent the belt clip 30 from being separated, and elongated receiving grooves 22 formed on the rear surface of the rear housing 20. It is composed of a projection plate 43 integrally formed on the slider 41 to slide the slider 41 downward to separate the belt clip 30 disposed in the.

The clamper 50 is a projection 50c of the pair of clampers 50 when the tension spring 51 provided on the shaft 51a and the release button 60 are released, as shown in FIG. 12. ), The projection of the pair of clampers 50 when pressing the lower operating member 52 and the release button 60, which are urged clockwise by the biasing force of the coil spring 51 so as to protrude, respectively. It consists of an upper operating lever 53 installed on the hinge shaft 50a to abut against the inclined surface 64 formed to be inclined inward to the lower portion of the release button 60 so as to retreat each of the 50c. It is.

The release button 60 is urged upward by the coil spring 62 to push the protrusion 50c of the clamper 50 toward the receiving groove 14 formed in the front housing 10.

The charging control unit 80 is a microprocessor 81 for controlling the overall operation of the charge of the battery of the mobile phone 12 and the secondary battery 210, as shown in Figure 14 and the travel adapter The microprocessor 81 performs step-up or step-down to charge the battery of the mobile phone 12 by receiving the DC power converted at 200 and the DC power (DC current and DC voltage) charged in the secondary battery 210. A first charging current detecting means 83 which receives a voltage converting means 82 output to the first and a DC power boosted or stepped down by the voltage converting means 82, detects a charging current, and outputs the charged current to the microprocessor 81; And the DC voltage stepped up or down by the voltage converting means 82 and the charging current detected by the first charging current detecting means 83, respectively, and computed by the microprocessor 81 to perform the processing of the mobile phone 12. Battery When the constant current and the constant voltage are not required to transmit, the mobile terminal 12 receives the charging current detected by the first charging current detecting means 83 according to a control signal output from the microprocessor 81. A first constant current / constant voltage adjusting means 84 that adjusts the battery to a constant current and a constant voltage to charge the battery, and receives the constant current / constant voltage adjusted by the first constant current / constant voltage adjusting means 84 and outputs the result from the microprocessor 81. The first switch 86 for intermittent battery charging of the mobile phone 12 via the output terminal 85 by the control signal, and the DC power (DC current and DC voltage converted by the travel adapter 200) Second charging current detection means 87 for detecting a charging current so as to charge the secondary battery 210 and outputting it to the microprocessor 81, and the second charging current detection means ( Receives the charging current detected in the 87 and the operation is processed in the microprocessor 81, if the constant current and constant voltage of a certain level required to charge the secondary battery 210 is output from the microprocessor 81 Second constant current / constant voltage adjusting means 88 receiving a charging current detected by the second charging current detecting means 87 and adjusting the constant current and the constant voltage to charge the secondary battery 210 at the same time as receiving a control signal. And a second switch which receives the constant current / constant voltage adjusted by the second constant current / constant voltage adjusting means 88 and regulates charging of the secondary battery 210 by a control signal output from the microprocessor 81. And the discharge of the DC power charged in the secondary battery 210 when the battery of the mobile phone 12 is not connected to the output terminal 85 and the output terminal 85. ) When the battery of the mobile phone 12 is connected to the output of the DC power charged in the secondary battery 210 to the voltage conversion means 82 to charge the battery of the mobile phone 12 Discharge prevention means 90 for intermittent, charge state display means 91 for displaying the charge of the secondary battery 210 while displaying the battery charge of the mobile phone 12, and the ambient temperature is constant When the temperature is higher than the temperature (45 ° C) or below the predetermined temperature (-5 ° C), the charging of the battery of the mobile phone 12 and the secondary battery 210 is prevented under the control of the microprocessor 81. The temperature detection means 92 which detects the ambient temperature and outputs it to the microprocessor 81 and the voltage output from the voltage conversion means 82, and at the same time receives reference voltage from the reference voltage setting means 93. Under the control of the microprocessor A / D value Vdd absolute value compensation means 94 for maintaining a constant charging current for charging the battery of the mobile phone 12 and controlling to accurately determine the voltage value charged in the mobile phone 12 battery. It is.

When the battery of the mobile phone 12 is connected to the + electrode and the-electrode of the output terminal 85, the discharge preventing means 90 has a low level voltage at the gate terminal through the bias resistors R39 and R54. Is applied and switched on to output the DC power charged in the secondary battery 210 to the voltage conversion means 82 through the protection means 211, and the + electrode and the-electrode of the output terminal 85 When the battery of the mobile phone 12 is not connected to the battery, a high level voltage is applied to the gate terminal through the bias resistors R39 and R54 to be switched off to charge the battery of the mobile phone 12. It consists of a transistor Q52.

The charging state display means 91 is a dual type light emitting diode LED1 as shown in Figs. 10, 13 and 14, and the dual type light emitting diode LED1 is a battery of the mobile phone 12 first. When charged, the dual type light emitting diode (LED1) emits light of red color only, indicating that the secondary battery 210 is being charged, and when the charging of the secondary battery 210 is completed first, the dual type light emitting diode is completed. The LED1 emits green light to indicate that the battery of the mobile phone 12 is being charged, and when the battery and the secondary battery 210 of the mobile phone 12 are both charged, the dual type light emitting diode LED1 is charged. ) Does not emit light, indicating that both the battery of the mobile phone 12 and the secondary battery 210 are charged. In the charging state display means 91, R62 and R63 are current limiting resistors.

The temperature detecting means 92 is a temperature detecting sensor for detecting an ambient temperature, and the secondary battery 210 has a built-in protection means 211 so as to detect and filter overcurrent and overvoltage.

In the drawing, reference numeral 202 denotes a cord for connecting the adapter 200 and the connector 208, 204 denotes a wire for electrically connecting the interface connector 70 and the charging control unit 80, and 206 denotes the charging. It is a charging wire for charging the DC power to the secondary battery 210 through the control unit 80.

Next, the operation and effects of the portable charging device 1000 of the mobile phone according to the embodiment of the present invention configured as described above will be described.

First, to charge the battery of the mobile phone 12 and the secondary battery 210 in the portable charging device 1000 of the mobile phone according to an embodiment of the present invention, shown in Figures 10 and 11 As described above, while the mobile phone 12 is pushed into the receiving groove 14 formed in the front housing 10, a charging terminal (not shown) formed at the bottom of the mobile phone 12 is connected to the interface connector 70. Connect.

At this time, the projections 50c of the clampers 50 respectively provided on both side walls of the accommodation groove 14 formed in the front housing 10 are inserted into the grooves formed on both sides of the mobile phone 12, respectively. 12 does not depart from the portable charging device 1000 of the mobile phone of the present invention. In other words, when the projections 50c of the clampers 50 respectively installed on both side walls of the accommodation groove 14 formed in the front housing 10 are inserted into the grooves formed on both sides of the mobile phone 12, FIG. 11. As shown in FIG. 2, the lower operation lever 52 integrally installed at the lower portion of the clamper 50 rotates counterclockwise about the hinge shaft 50a against the counter force of the coil spring 51. At the same time, the upper operating lever 53 also easily pushes the mobile phone 12 into the receiving groove 14 formed in the front housing 10 as it rotates counterclockwise around the hinge shaft 50a. I can put it.

When the mobile phone 12 is completely mounted in the receiving groove 14 formed in the front housing 10, the upper actuating lever 53 and the lower actuating lever 52 by the force of the coil spring 51. ) Rotates clockwise around the hinge shaft 50a, so that the projections 50c of the clamper 50 are inserted into grooves formed on both sides of the mobile phone 12, respectively, to allow the mobile phone 12 to be rotated. This is firmly fixed to the portable charging device 1000 of the mobile phone of the present invention.

As such, the connector 208 installed on one side of the cord 202 in a state in which the mobile phone 12 is infiltrated into the receiving groove 14 of the front housing 10 of the portable charging device 1000 of the mobile phone of the present invention. Is electrically connected to a charging connector (not shown) installed in the portable charging device 1000 of the mobile phone according to the present invention, and then the plug 200a of the travel adapter 200 installed on the other side of the cord 202. ) Is connected to 110Vac, 220Vac or a vehicle battery voltage line, and receives the AC voltage through the 110Vac, 220Vac or the vehicle battery voltage line in the travel adapter 200 to convert to a DC voltage to the charge control unit 80 Supplied. Accordingly, the battery of the mobile phone 12 and the secondary battery 210 are simultaneously charged with a DC voltage by the control of the charging control unit 80. At this time, the dual type light emitting diode LED1 is It emits orange color.

On the other hand, when the battery of the mobile phone 12 is first charged during the charging, the dual type light emitting diode LED1 emits light of red color only to indicate that the secondary battery 210 is being charged. When the charging of the battery 210 is completed first, the dual-type light emitting diode LED1 emits green light to indicate that the battery of the mobile phone 12 is being charged, and the battery of the mobile phone 12 and the When both of the secondary batteries 210 are charged, the dual type light emitting diode LED1 does not emit light, indicating that both the battery of the mobile phone 12 and the secondary battery 210 are charged.

When the battery of the mobile phone 12 and the secondary battery 210 is charged as described above, by pressing the release button 60 of the portable charging device 1000 of the mobile phone according to an embodiment of the present invention After the projection 50c of the clamper 50 is immersed therein, the mobile phone 12 may be detached from the portable charging device 1000 of the mobile phone according to an embodiment of the present invention and carried on a call. .

In the operation of immersing the protrusion 50c of the clamper 50 inwardly, as shown in FIG. 12, when the release button 60 is pressed, the release button 60 is lowered while pressing the coil spring 62. As such, the inclined surface 64 formed integrally with the lower part of the release button 60 rotates the upper operation lever 53 of the release button 60 in a counterclockwise direction about the hinge axis 50a. Accordingly, the lower actuating lever 52 rotates clockwise about the shaft 51a against the bias force of the coil spring 51 so that the protrusion 50c of the clamper 50 moves to the front housing 10. By entering the inside of the mobile phone 12 can be easily separated from the portable charging device 1000 of the mobile phone of the present invention.

Then, in the portable charging device 1000 of the mobile phone according to an embodiment of the present invention by pressing the upper portion of the movable member 34 of the belt clip 30, the lower portion of the movable member 34 is the fixing member 33 When the movable member 34 is released while the waist belt (not shown) is positioned between the fixing member 33 and the movable member 34, the movable member 34 is coil spring 35. It is fixed to the waist belt by clamping the waist belt by the force of).

As described above, if the portable charging device 1000 of the mobile phone according to an embodiment of the present invention is uncomfortable when sitting or bending the waist while wearing the waist belt, the portable charging device 1000 of the mobile phone of the present invention is When turning clockwise or counterclockwise, a turning groove 32 of the belt clip 30 is formed in the fixing member 33 while turning at a predetermined angle (for example, 30 degrees) (not shown). Is rotated within.

At this time, the engaging member 32c disposed on the rotating plate 32 of the belt clip 30 is rotated while contracting the coil spring 32d so that the front end of the engaging member 32c receives the fixing member 33. Stopping while being inserted into the groove 33b formed on the inner circumferential surface of the groove, and if it continues to rotate, it can be rotated up to 90 degrees in the clockwise or counterclockwise direction. The assembly of the front housing 10 and the rear housing 20 of the can be positioned in the longitudinal direction of the waist belt is easy to carry.

The battery of the mobile phone 12 is discharged according to the use of the mobile phone 12, and the DC power charged in the secondary battery 210 charges the battery of the mobile phone 12. When the secondary battery 210 is discharged, in the receiving groove 14 formed in the front housing 10 of the portable charging device 1000 of the mobile phone 12 according to an embodiment of the present invention worn on the waist belt. The mobile phone 12 is pushed in, a charging terminal (not shown) formed at the bottom of the mobile phone 12 as described above is connected to the interface connector 70, and then to one side of the cord 202 The installed connector 208 is electrically connected to a charging connector (not shown) installed in the portable charging device 1000 of the mobile phone according to the present invention, and then the travel adapter 200 installed on the other side of the cord 202. ) Plug 110a to 110Vac, 220Vac or vehicle By connecting the battery voltage line and charges the battery and a secondary battery 210 of the mobile phone 12 under the control of the charging control unit 80.

Next, the charging operation of the charging control unit 80 will be described in detail.

First, the DC power converted by the travel adapter 200 is boosted or stepped down by the voltage converting means 82 to be output to the microprocessor 81 and to the first charging current detecting means 83. Output

The first charging current detecting unit 83 receives a DC voltage stepped up or down by the voltage converting unit 82 to detect a charging current and outputs the charging current to the microprocessor 81, and at the same time, the first constant current / The microprocessor 81 receives the DC voltage stepped up or down by the voltage converting means 82 and the charging current detected by the first charging current detecting means 83. If it is not a constant level and constant voltage of a predetermined level required to charge the battery of the mobile phone 12 by processing, the microprocessor 81 outputs a control signal to the first constant current / constant voltage adjusting means 84, The first constant current / constant voltage adjusting means 84 adjusts the constant current and the constant voltage of a predetermined level required to charge the battery of the mobile phone 12 and outputs the same to the first switch 86. do.

The first switch 86 receives a control signal for charging the battery of the mobile phone 12 from the microprocessor 81 and is switched on to switch the mobile phone through the + and − electrodes of the output terminal 85. Charge the battery of 12).

At the same time, the DC power converted by the travel adapter 200 detects the charging current in the second charging current detecting means 87 and outputs the charging current to the microprocessor 81, and adjusts the second constant current / constant voltage. Output to the means 88, and the microprocessor 81 receives and processes the charging current detected by the second charging current detecting means 87 to perform a constant processing to charge the secondary battery 210 at a predetermined level and When the voltage is not constant, the microprocessor 81 outputs a control signal to the second constant current / constant voltage adjusting means 88, and the secondary battery 210 is controlled by the second constant current / constant voltage adjusting means 88. It is adjusted to a constant level of constant current and constant voltage necessary to charge the output to the second switch (89).

At this time, the second switch 89 is switched on by the control signal output from the microprocessor 81 to adjust the constant current and the constant voltage of the constant level regulated by the second constant current / constant voltage adjusting means 87 to the secondary. The overcurrent and overvoltage are detected and filtered by the protection means 211 inherent in the battery 210, and then charged in the secondary battery 210.

Next, a method of charging the battery of the mobile phone 12 with the DC power charged in the secondary battery 210 will be described.

When the battery of the mobile phone 12 is exhausted as the mobile phone 12 is used, to charge the DC power charged in the secondary battery 210 to the battery of the mobile phone 12, the The mobile phone 12 is pushed into the receiving groove 14 of the front housing 10.

At this time, as the charging terminal (not shown) installed below the mobile phone 12 is connected to the interface connector 70, the battery of the mobile phone 12 connected to the output terminal 85 is connected. Therefore, a low level voltage is applied to the gate terminal through the bias resistors R39 and R54 to the gate terminal of the field effect transistor Q52 of the discharge preventing means 90 so that the field effect transistor Q52 is switched on. And output the DC power charged in the secondary battery 210 to the voltage conversion means 82 through the protection means 211.

The voltage converting means 82 receives the DC power charged in the secondary battery 210 through the protection means 211 and the discharge preventing means 90 to charge the battery of the mobile phone 12. The output of the microprocessor 81 is boosted or stepped down so as to be output to the microprocessor 81 and to the first charging current detecting means 83, and the charging rectification detected by the first charging current detecting means 83 Output to the processor 81 and the first constant current / constant voltage adjusting means 84, respectively.

Accordingly, the microprocessor 81 receives the DC voltage stepped up or down by the voltage converting means 82 and the charging current detected by the first charging current detecting means 83 to perform arithmetic processing on the mobile phone 12. When the constant current and the constant voltage of the predetermined level required to charge the battery of the battery is not, the microprocessor 81 outputs a control signal to the first constant current / constant voltage adjusting means 84, and the first constant current / constant voltage adjusting means ( 84) is adjusted to a constant level of constant current and constant voltage required to charge the battery of the mobile phone 12 and output to the first switch (86).

The first switch 86 receives a control signal for charging the battery of the mobile phone 12 from the microprocessor 81 and is switched on to switch the mobile phone through the + and − electrodes of the output terminal 85. Charge the battery of 12).

On the other hand, when the battery of the mobile phone 12 connected to the output terminal 85 is not connected, the bias resistors R39 and R54 are connected to the gate terminals of the field effect transistor Q52 of the discharge preventing means 90. The high level voltage is applied to the gate terminal through the N) so that the field effect transistor Q52 is switched off to prevent the DC power charged in the secondary battery 210 from being naturally discharged.

15 is a view illustrating a state in which the portable charging device 1000 of the mobile phone according to an embodiment of the present invention is coupled to a vehicle hands-free kit for charging, and FIG. 16 is a mobile phone according to an embodiment of the present invention. Is a diagram illustrating a state of charging by mounting the portable charger of the table charger.

15 and 16, after detaching the belt clip 30 detachably coupled to the back of the portable charging device 1000 of the mobile phone according to one embodiment of the present invention, one of the present invention The receiving groove 22 formed on the rear surface of the rear housing 100 of the portable charging device 1000 according to the embodiment and the vehicle hands-free kit 220 or the table charger 230 are coupled by a bracket 224. After fixing, the mobile phone 12 is pushed into the receiving groove 14 formed in the front of the front housing 10 to be mounted.

Next, the connector 226 connected to the vehicle hands-free kit 220 or the table charger 230 is connected to a charging connector (not shown) of the portable charging device 1000 according to an embodiment of the present invention. The vehicle hands-free kit 220 or the plug 228 of the table charger 230 to a vehicle battery or electrically connected to a 110Vac / 220Vac or vehicle battery voltage line. According to the battery of the mobile phone 12 or the secondary battery 210 built in the portable charging device according to an embodiment of the present invention can be charged.

Next, the belt clip 30 detachably coupled to the rear surface of the portable charging device 1000 of the mobile phone according to the embodiment of the present invention, that is, the receiving groove 22 formed on the rear surface of the rear housing 20. The removal and installation of the) will be described.

First, to remove the belt clip 30 is coupled to the receiving groove 22 formed on the rear of the rear housing 20 of the portable charging device 1000 of the mobile phone according to an embodiment of the present invention, Figure 7 and In FIG. 8, when the projection plate 43 integrally formed on the slider 41 of the lock member 40 is pushed down, the lock member (compresses the spring against the force of the spring not shown). As the slider 41 of the lower portion 40 moves downward, the grooves 31b formed at the lower portion of the coupling member 31 of the belt clip 30 are formed with the protrusions 42 formed integrally with the front end of the slider 41. Escape from).

At this time, when the fixing member 33 and the movable member 34 of the belt clip 30 are lifted up and down, the pair of protrusions integrally formed at the front end (upper part) of the coupling member 31 31a) of the rear housing 20 of the portable charging device 1000 of the mobile phone according to an embodiment of the present invention while exiting from the upper receiving groove (not shown) formed on the rear of the rear housing 20 The belt clip 30 coupled to the receiving groove 22 formed on the rear side is separated.

In order to couple the belt clip 30 separated in this way to the receiving groove 22 formed on the rear of the rear housing 20 of the portable charging device 1000 of the mobile phone according to an embodiment of the present invention, FIG. 8 and integrally with the front end portion (top) of the belt clip 30 in a state in which the protrusion plate 43 formed integrally with the slider 41 of the lock member 40 is pushed down. The fixed member 33 and the movable member 34 of the belt clip 30 are pushed into the receiving groove (not shown) formed on the rear surface of the rear housing 20 by the pair of protrusions 31a formed. It is pushed into the receiving groove 22 formed on the rear surface of the housing 20.

Next, when the gripping of the projection plate 43 integrally formed on the slider 41 of the lock member 40 is released, the slider (not shown) is applied by the force of the spring (or elastic member) not shown. As the 41 is slid upwards, the projection 42 integrally formed at the tip of the slider 41 is inserted into the groove 31b formed at the lower portion of the coupling member 31 of the belt clip 30. The coupling member 31 of the 30 is firmly coupled to the receiving groove 22 of the rear housing 20.

Therefore, the present invention can be easily attached to and detached from the waist belt using a belt clip, the mounting position can be changed by turning when attached to the waist belt, the DC power source converted to DC in the travel adapter 200 The secondary battery 210 and the battery of the mobile phone 12 can be charged at the same time, the discharge when the mobile phone 12 is not electrically connected to the receiving groove 14 of the front housing 10 The prevention means 90 may be turned off to prevent discharge of the charging power charged in the secondary battery 210.

In addition, the present invention can not only prevent the charging when the ambient temperature is higher than a certain temperature (45 ℃) or lower than the constant temperature (-5 ℃), but also at a temperature between -5 ℃ to 45 ℃ The DC power charged in the secondary battery 210 can be easily charged to the battery of the mobile phone 12, and electrically connected to the hands-free kit 220 to use the vehicle battery to The battery can be easily charged and electrically connected to the desktop charging cradle 230 to simultaneously charge the battery of the secondary battery 210 and the mobile phone 12.

Next, a charging control method for charging the battery and the secondary battery 210 of the mobile phone by using the portable charging device of the mobile phone according to an embodiment of the present invention will be described with reference to FIG.

17 is a flowchart for explaining a method for charging a battery and a secondary battery of a mobile phone in a portable charging device of a mobile phone according to an embodiment of the present invention.

First, in step S1, whether the plug 200a of the travel adapter 200 is connected to a power line (for example, 110 Vac, 220 Vac or a vehicle battery voltage line) is determined by the first charging current / voltage detecting means 83. When the detected signal is determined by the microprocessor (travel adapter connection discrimination step), and when the plug 200a of the travel adapter 200 is connected to the power line in the travel adapter connection discrimination step (YES) In step S2, the battery of the mobile phone 12 is inserted into the receiving groove 14 formed in the front housing 10, the output terminal 85 (also referred to as a charging terminal) formed in the lower portion of the mobile phone 12 The microprocessor 81 receives the signal detected by the output terminal 85 to determine whether or not the interface connector 70 is electrically connected (first output terminal connection discrimination step), If the output terminal 85 of the mobile phone 12 and the interface connector 70 are electrically connected in the first output terminal connection discrimination step (YES), the process proceeds to step S3 and the ambient temperature detection means ( 92 determines whether or not the ambient temperature detected by the step is equal to or lower than the charge lower limit temperature (-5 占 폚) (first charge lower limit temperature determination step), and the charge lower limit temperature (-5 占 폚) in the first charge lower limit temperature determination step. If not (NO), go to Step S4 to determine whether the ambient temperature detected by the ambient temperature detecting means 92 is equal to or higher than the charge upper limit temperature (45 ° C) (first charge upper limit temperature determination step). ), If the charging upper limit temperature determination step is not equal to or higher than the charging upper limit temperature (45 ° C.) (NO), the process proceeds to step S5 to indicate the current of the battery of the mobile phone 12 and the secondary battery 210. The voltage / voltage A / D value from the charging current / voltage detecting means 83 Respectively detect and output to the microprocessor 81 (first charge current / voltage A / D value detection step), and the battery of the mobile phone 12 in the first charge current / voltage A / D value detection step; After reading the charge current / voltage A / D values of the secondary battery 210 into the microprocessor 81, respectively, the process proceeds to step S6 to determine the charge current / voltage of the mobile phone 12 and the secondary battery 210. FIG. The A / D value is compensated for by the A / D value VDD absolute value compensation means 94 (first charging current / voltage A / D value VDD absolute value compensation step).

Next, the microprocessor 81 receives the charging current flowing through the output terminal 85 to determine whether the charging current of the mobile phone 12 is less than a limit current (400 mA). (First limit current determination step), and if the result determined in the first limit current determination step is less than the limit current (YES), the process proceeds to step S8 and the mobile phone 12 at the charge limit current of the mobile phone 12. ), The excess current is calculated by the microprocessor 81 (the excess current calculation step), and the flow proceeds to step S9 where the charging current of the mobile phone 12 is cut off (CUT-OFF; 50 mA) current. The microprocessor 81 receives the first charging current detected by the first charging current / voltage detecting means 83 (first cut-off current determination step), and determines whether or not it is less than or equal to the first cut-off current. At the discrimination step If the charging current of the one phone 12 is less than the cut-off current (YES), the flow advances to step S10 to determine whether the charging voltage of the mobile phone 12 is 3.9 Vdc or more (first phone charging voltage determination step). In the first phone charging voltage determination step, when the phone charging voltage is 3.9 Vdc or more (YES), the microprocessor 81 may turn off the battery charging of the mobile phone 12 in step S11. The dual type light emitting diode LED1 is green by the control signal output from the microprocessor 81 while outputting an off control signal to the first switch 86 to terminate (off) the battery charging of the mobile phone 12. Light is emitted (first phone battery charging end step).

Subsequently, the microprocessor 81 calculates a total limit charging current for charging the secondary battery 210 by summing the internal total limit charging current (200 mA) and the extra phone charging current in the microprocessor 81 (total). Limit charge current calculation step), the process proceeds to step S13, where the second charge current / voltage detecting means 87 detects whether the charge current of the secondary battery 210 is less than the internal total limit charge current. Is determined by the microprocessor 81 which has received a value of less than the internal total limit charging current, and the determination result of the determination step less than the internal total limit charging current indicates that the charging current of the secondary battery 210 is internally integrated. If less than the limit charging current (YES), the flow advances to step S14 to determine whether the charging current of the secondary battery 210 is less than or equal to the secondary battery cut-off current (50 mA) (first first). If the determination result of the secondary battery cut-off current determination step) or the first secondary battery cut-off current determination step is less than or equal to the secondary battery cut-off current (50 mA) (YES), the flow advances to step S15 and the secondary battery. It is determined whether or not the charging voltage of 210 is 3.9 Vdc or more (first secondary battery charging determination step), and as a result of the determination of the first secondary battery charging determination step, the charging voltage of the secondary battery 210 is increased. If it is 3.9 Vdc or more (YES), the microprocessor 81 outputs an off control signal to the second switch 89 to turn off the charging of the secondary battery 210 in step S16. While the battery charge of the battery 210 is terminated (off), the light emission of the dual type light emitting diode LED1 is turned off by the control signal output from the microprocessor 81 (first secondary battery charge termination step). As a result of the determination of the first charge lower limit temperature determination step S3, If the ambient temperature detected by the ambient temperature detection means 92 is equal to or lower than the charge lower limit temperature (-5 ° C), the process proceeds to step S20, whereby the microprocessor 81 sends a charge-off control signal to the first switch 86. Outputs to turn off the charge of the battery of the mobile phone 12 and the secondary battery 210, and returns to the first charge lower limit temperature determination step (step S3) to determine the first charge lower limit temperature determination step (step S3). The following operation is repeated, and the dual type light emitting diode LED1 emits red and green light and emits orange light so that the battery and the secondary battery 210 of the mobile phone 12 are not charged. If the ambient temperature detected by the ambient temperature detection means 92 is equal to or higher than the charge upper limit temperature (45 ° C) (YES), the flow advances to step S21. Further The microprocessor 81 outputs a charge-off control signal to the first switch 86 to turn off the charge of the battery of the mobile phone 12 and the secondary battery 210 and to determine the charge upper limit temperature step ( Returning to step S4), the operation below the first charge upper limit temperature determination step (step S4) is repeatedly performed, and the dual-type light emitting diode LED1 is emitted in red and green to emit light in orange, and the mobile Indicates that the battery of the phone 12 and the secondary battery 210 are not being charged. As a result of the determination of the first limit current determination step (step S7), the charging current of the mobile phone 12 is limited ( limit) If it is not less than 400 mA, that is, if it is 400 mA or more (NO), the control signal output from the microprocessor 81 is sent to the first constant current / constant voltage adjusting means 84 by going to step S22. Of Outputting a voltage control signal and adjusting the constant current / constant voltage control control signal by the first constant current / constant voltage adjusting means 84 to reduce the charging current of the mobile phone 12 to less than an upper limit of charge, and to determine the first limit current. (Step S7) When the following operation | movement is repeatedly performed and the determination result of the said 1st cut-off current determination step (step S9) is not, the charging current of the said mobile phone 12 is not below cut-off current (NO). In step S23, the microprocessor 81 outputs a constant current / constant voltage adjustment control signal to the first constant current / constant voltage adjusting means 84 to adjust the constant current / constant voltage in the first constant current / constant voltage adjusting means 84. To control the mobile phone 12 above the lower limit of the charging current. As a result of the determination of the first phone charging voltage determination step (step S10), the phone charging is performed in the first phone charging voltage determination step. If the voltage is not 3.9 Vdc or more (NO), the process proceeds to step S24 and continues charging the mobile phone 12, and returns to the first phone charging voltage determination step (step S10) to determine the first phone charging voltage. When the operation of the step (step S10) or less is repeated, and the determination of the determination step (step S13) below the internal comprehensive limit charging current is performed, the charging current of the secondary battery 210 is not less than the internal comprehensive limit charging current. (NO), the microprocessor 81 outputs a constant current / constant voltage adjustment control signal to the second constant current / constant voltage adjusting means 88 by the second constant current / constant voltage adjusting means 88. While controlling the secondary battery 210 to the charge current total limit or more and at the same time, the process returns to the determination step below the internal comprehensive limit charging current (step S13) to determine less than the internal total limit charging current. The following steps (step S13) are repeated. Further, as a result of the determination of the first secondary battery cut-off current determination step (step S14), the secondary battery 210 charge current is equal to or less than the internal total limit charge current. If it is not (50 mA) (NO), go to step S29 and output the constant current / constant voltage adjustment control signal from the microprocessor 81 to the second constant current / constant voltage regulating means 88 to adjust the second constant current / constant voltage. The means 88 controls the secondary battery 210 to the lower limit of the charge current or more, and returns to the first secondary battery cut-off current determination step (step S14) to return the first secondary battery. The operation below the cut-off current determination step (step S14) is repeatedly performed, and as a result of the determination of the first secondary battery charging voltage determination step (step S15), the charging voltage of the secondary battery 210 is 3.9 Vdc or more. If not (NO), go to Step S30. The secondary battery 210 is continuously performed, and the operation of returning to the first secondary battery charging voltage determination step (step S15) is repeated and the operations below the first secondary battery charging voltage determination step (step S15) are repeated. Do it.

Next, a charging control method of charging a DC power charged in a secondary battery to a battery of a mobile phone using a portable charging device for a mobile phone according to an embodiment of the present invention will be described with reference to FIG.

18 is a flowchart for explaining a charging control method for charging a mobile phone with a DC power charged in a secondary battery in a portable charging device for a mobile phone according to an embodiment of the present invention.

As a result of the determination of the travel adapter connection discrimination step (step S1), when the plug 200a of the travel adapter 200 is not connected to the power line (NO), the process proceeds to step S100 and the The battery is inserted into the receiving groove 14 formed in the front housing 10 so that the charging terminal (not shown) formed at the bottom of the mobile phone 12 and the interface connector 70 is electrically connected. The microprocessor 81 receives the signal detected by the terminal 85 (second charging terminal connection discrimination step), and interfaces with the charging terminal of the mobile phone 12 in the second charging terminal connection discrimination step. If the connector 70 is electrically connected (YES), go to Step S101 to determine whether or not the ambient temperature detected by the ambient temperature detecting means 92 is equal to or lower than the charge lower limit temperature (-5 ° C). (Second charge lower limit temperature determination step), if the charge lower limit temperature determination step is not equal to or lower than the charge lower limit temperature (-5 ° C) (NO), the process proceeds to step S102, and the ambient temperature detection means 92 Is determined whether the ambient temperature detected is higher than or equal to the charging upper limit temperature (45 ° C.) (second charging upper limit temperature determination step), and when the second charging upper limit temperature determination step is not equal to or higher than the charging upper limit temperature (45 ° C.) ( In the case of NO), the process proceeds to step S103, where the secondary battery 210 is charged off while the dual type light emitting diode LED1 emits green light to indicate that the secondary battery 210 is not being charged (secondary). Battery charge-off step). Next, the flow advances to step S104 to detect the charge current / voltage A / D value of the battery of the mobile phone 12 by the second charge current / voltage detection means 83, so that the microprocessor 81 ) And (second charging current / voltage A / D value detection switch) ), After reading each of the charging current / voltage A / D values of the mobile phone 12 detected in the second charging current / voltage A / D value detection step by the microprocessor 81, the process proceeds to step S105. The A / D value VDD absolute value compensating means 94 compensates (second charging current / voltage A / D value VDD absolute value compensating step). Next, the flow proceeds to step S106 where the charging current of the mobile phone 12 is limited. When the microprocessor 81 determines whether it is less than the limit current (400 mA) (second limit current determination step), and the result determined by the second limit current determination step is less than the limit current (YES). In step S107, the charging current of the mobile phone 12 is cut off (CUT-OFF; 50 mA) the microprocessor 81 determines whether the current is less than (second cut-off current determination step), and if the charging current of the mobile phone 12 is less than the cut-off current in the second cut-off current determination step ( YES), the flow proceeds to step S108 to determine whether the charging voltage of the mobile phone 12 is 3.9 Vdc or more (second phone charging voltage determination step), and the phone charging voltage is increased in the second phone charging voltage determination step. If 3.9 Vdc or more (YES), the microprocessor 81 outputs an off control signal to the first switch 86 to turn off the battery charging of the mobile phone 12 by going to step S109. While the battery charging of the phone 12 is terminated (off), the green light of the dual type light emitting diode LED1 is turned off by the control signal output from the microprocessor 81 (second phone battery charging end step). As a result of the determination of the second charge lower limit temperature determination step (step S101), when the ambient temperature detected by the ambient temperature detection means 92 is equal to or lower than the charge lower limit temperature (-5 ° C) (YES), the operation proceeds to step S110. Further, the microprocessor 81 outputs a charge-off control signal to the first switch 86 to turn off the battery charge of the mobile phone 12 and return to the second charge lower limit temperature determination step (step S101). By repeating the operation below the second charge lower limit temperature determination step (step S101), the dual-type light emitting diode LED1 is emitted in red and green, and then in orange. When the battery is not charged and the ambient temperature detected by the ambient temperature detection means 92 is greater than or equal to the charge upper limit temperature (45 ° C) as a result of the determination of the second charge upper limit temperature determination step. In the case of YES, the microprocessor 81 outputs a charge-off control signal to the first switch 86 to turn off the battery charge of the mobile phone 12 and to set the second charge upper limit temperature. Returning to the determination step (step S102), the operation below the second charge upper limit temperature determination step (step S102) is repeatedly performed, and the dual type light emitting diode LED1 is emitted in red and green to emit orange light. The battery of the mobile phone 12 is not charged. As a result of the determination of the second limit current determination step (step S106), the charging current of the mobile phone 12 is a limit current (400 mA). If not less than, i.e., 400 mA or more (NO), the process proceeds to step S113 where the constant current / constant voltage control control signal output from the microprocessor 81 is output to the first constant current / constant. Outputs to the voltage adjusting means 84, and regulates the constant current / constant voltage by the first constant current / constant voltage adjusting means 84 to reduce and control it below the upper limit of the charging current of the mobile phone 12, and to determine the second limit current. Returning to step (step S106), the operation following the second limit current determination step (step S106) is repeatedly performed, and as a result of the determination of the second cut-off current determination step (step S107), the mobile phone 12 If the charging current is not lower than the cutoff current (NO), the flow advances to step S114 to output the constant current / constant voltage control control signal output from the microprocessor 81 to the first constant current / constant voltage adjusting means 84. The first constant current / constant voltage regulating means 84 adjusts the constant current / constant voltage to control the upper limit of the charging current of the mobile phone 12 or more. [0046] The determination of the second phone charging voltage determination step (step S108). As a result, when the charging voltage of the mobile phone 12 is not 3.9 Vdc or more (NO), the mobile terminal 12 continues to charge the mobile phone 12 and emits light of the dual-type light emitting diode LED1 in green. In this case, the mobile phone 12 is being charged, and the operations below the second phone charging voltage determination step (step S108) are repeatedly performed.

Next, a charging control method for charging only a secondary battery using a portable charging device for a mobile phone according to an embodiment of the present invention will be described with reference to FIG.

19 is a flowchart for explaining a charging control method for charging only a secondary battery in a portable charging device of a mobile phone according to one embodiment of the present invention.

As a result of the determination of the charging terminal connection discrimination step (step S2), when the charging terminal of the mobile phone 12 and the interface connector 70 are not electrically connected (NO), the process proceeds to step S200 and the ambient temperature. It is determined whether or not the ambient temperature detected by the detection means 92 is equal to or lower than the charge lower limit temperature (-5 ° C) (third charge lower limit temperature determination step), and the charge lower limit temperature (−) is determined in the third charge lower limit temperature determination step. 5 ° C.) or less (NO), proceed to step S201 to determine whether the ambient temperature detected by the ambient temperature detecting means 92 is the charge upper limit temperature (45 ° C.) (third charge upper limit temperature). Discrimination step), when the third charging upper limit temperature determination step is not equal to or higher than the charging upper limit temperature (45 ° C.) (step NO), the process proceeds to step S202 to turn off the charging line of the battery of the mobile phone 12; Of dual type light emitting diode (LED1) The green light is turned off (third mobile phone battery charge off step). Next, the flow advances to step S203 to determine the current / voltage A / D value of the secondary battery 210 by the second charge current / voltage detection means 87. Are detected and output to the microprocessor 81 (third charging current voltage A / D value detection step), and the current voltage of the secondary battery 210 in the third charging current voltage A / D value detection step. After reading the A / D value, the flow advances to step S204 to compensate the charging current / voltage A / D value of the secondary battery 210 in the A / D value VDD absolute value compensating means 94 (third charging current). / Voltage A / D value VDD absolute value compensation step).

Next, the process proceeds to step S205 in which the micro-receiving charge current detected by the second charge current / voltage detecting means 87 determines whether the charge current of the secondary battery 210 is less than a limit current (400 mA). If it is determined by the processor 81 (third limit current determination step), and as a result of the third limit current determination step, the charging current of the secondary battery 210 is not less than the limit current (400 mA). (YES), the flow proceeds to step S206 where the second charging current / voltage detecting means 87 detects whether the charging current of the secondary battery 210 is lower than the cut-off (CUT-OFF; 50 mA) current. If the microprocessor 81 that has received the second charging current is discriminated (third cut-off current discrimination step), and the result of the discrimination of the third cut-off current discrimination step is less than or equal to the cutoff current (YES), the step Proceeding to S207, whether the charge voltage of the secondary battery 210 is 3.9 Vdc or more If the second secondary battery charge voltage determination step is determined, and the determination result of the second secondary battery charge voltage determination step is that the secondary battery 210 charge voltage is 3.9 Vdc or more (YES). In step S208, the microprocessor 81 outputs an off control signal to the second switch 86 to turn off the charging of the secondary battery 210 to end the charging of the second secondary battery 210. The dual type light emitting diode LED1 is turned off (second secondary battery charging end step) by the control signal output from the microprocessor 81 (off). The third charge lower limit temperature determination step (step S200). If the ambient temperature detected by the ambient temperature detecting means 92 is equal to or lower than the charge lower limit temperature (-5 ° C) (YES), the process proceeds to step S210 and the microprocessor 81 performs the second operation. A charge off control signal is supplied to the switch 88. Outputs to turn off the charge of the secondary battery 210, returns to the third charge lower limit temperature determination step (step S200), and repeatedly performs the operation below the second charge lower limit temperature determination step (step S100). , The dual type light emitting diode LED1 emits red and green light to emit orange light, indicating that the battery of the secondary battery 210 is not being charged, and determining the second charge upper limit temperature determination step. If the ambient temperature detected by the ambient temperature detecting means 92 is equal to or higher than the charge upper limit temperature (45 ° C.) (YES), the process proceeds to step S211 and the microprocessor 81 sends the second switch 88 to the second switch 88. Outputs a charge-off control signal to turn off the charge of the secondary battery 210 and returns to the second charge upper limit temperature determination step (step S201) to be equal to or less than the second charge upper limit temperature determination step (step S201). The operation is repeated, and the dual type light emitting diode LED1 emits red and green light and emits orange light, indicating that the secondary battery 210 is not charged. As a result of the determination of the step (step S205), if the charging current of the secondary battery 210 is not less than the limit current (400 mA), that is, if it is 400 mA or more (NO), the process proceeds to step S212 and the microprocessor. Outputs the constant current / constant voltage adjustment control signal output from the 81 to the second constant current / constant voltage adjusting means 88 to adjust the constant current / constant voltage in the second constant current / constant voltage adjusting means 88 to control the secondary battery ( 210) The control is reduced to less than the upper limit of the charging current, and the operation returns to the third limit current determination step (step S205), and the operations below the third limit current determination step (step S205) are repeatedly performed. As a result of the determination of the third cut-off current determination step (step S206), when the charging current of the secondary battery 210 is not lower than or equal to the cut-off current (NO), the process proceeds to step S213 and the microprocessor 81 Outputs a constant current / constant voltage regulation control signal output from the second constant current / constant voltage adjusting means 88 to adjust the constant current / constant voltage by the second constant current / constant voltage adjusting means 88 of the secondary battery 210. The secondary battery 210 charge voltage is set to 3.9 in the second secondary battery charge voltage determination step as a result of the determination of the second secondary battery charge voltage determination step (step S207). If it is not Vdc or more (NO), the process proceeds to step S214 and the secondary battery 210 is charged by emitting the dual type light emitting diode LED1 in red while continuing to charge the secondary battery 210. Indicate that there is, and said 2 secondary battery returns to the charging voltage determination step (step S207) and the second secondary battery charging voltage determination is performed by repeating the following steps (step S207).

Next, a compensation method for compensating a phone charging current / voltage A / D value in a portable charging device of a mobile phone according to an embodiment of the present invention will be described.

20 is a flowchart illustrating a method of compensating an absolute value of the phone charging current voltage A / D value VDD in the portable charging device of a mobile phone according to an embodiment of the present invention.

As shown in FIG. 20, the charging current / voltage A / D value VDD absolute value compensation step (step S6) converts the absolute voltage (2.5Vdc) of the reference voltage set in the reference voltage setting means 93 in step S301 into the micrometer. The processor 81 reads the absolute value of 2.5 Vdc, and confirms the relative operating voltage. In step S302, the operating voltage obtained in S301, the reference operating voltage (5 Vdc), and the VDD absolute value are read before the operating voltage is compensated. The compensation value (actual value) is obtained by compensating the absolute value of VDD with one A / D value.

In other words, (Read absolute value 2.5Vdc with reference operating voltage 5Vdc A / D Absolute value: Reference operating voltage (5Vdc) = Absolute value 2.5Vdc reading A / D value with operating voltage 5Vdc: Operating voltage).

In the above formula, operating voltage = (read absolute value 2.5Vdc A / D value as operating voltage) × (reference operating voltage (5Vdc) / (reference operating voltage 5Vdc to A / D absolute value 2.5Vdc),

Actual value (compensated value) = A / D × operating voltage / reference voltage 5Vdc read as operating voltage.

In the above description, the portable charging device of the mobile phone of the present invention has been described as an example carrying the waist belt, the present invention is not limited to this, for example, the belt at the edge of the top or pocket of the bottom Of course, it can also be carried by using a clip.

In the above description, the battery is mounted on the mobile phone 12 in the accommodating groove 14 of the front housing 10 together to charge the battery of the mobile phone 12 as an example, but the present invention has been described. The present invention is not limited thereto. For example, the battery may be charged by only inserting the battery into the accommodating groove 14.

In the above description, the specific embodiments have been shown and described, but the present invention is not limited thereto, for example, by those skilled in the art without departing from the concept of the present invention. Of course, the design can be changed in various ways.

As described above, according to the charging control method of the mobile charging device for a mobile phone of the present invention, the secondary battery and the battery of the mobile phone can be simultaneously charged by the DC power converted by the travel adapter into direct current, and the mobile phone has a front housing. Discharge of the charging power charged in the secondary battery can be prevented when it is not electrically connected to the receiving groove of the battery, and the ambient temperature is higher than a certain temperature, for example, higher than the charging upper limit temperature (45 ℃) or constant temperature. When the temperature is lower than the lower temperature, for example, lower than the charging lower limit temperature (-5 ° C), charging can be prevented, and the DC power charged in the secondary battery can be easily charged to the battery of the mobile phone, and hands-free. Electrically connected to the kit allows you to easily charge your mobile phone's battery using a car battery, as well as a desktop charging cradle. To to ever connected to use the travel adapter has a very excellent effect that the secondary battery and the mobile phone number of charging the battery at the same time.

Claims (5)

A travel adapter connection judging step of judging by the microprocessor receiving the signal detected by the first charging current / voltage detecting means 83 whether the plug 200a of the travel adapter 200 is connected to the power line; When the plug 200a of the travel adapter 200 is connected to the power line in the travel adapter connection determination step, the battery of the mobile phone 12 is inserted into the receiving groove 14 formed in the front housing 10. The microprocessor 81 receives a signal detected by the output terminal 85 to determine whether the output terminal 85 and the interface connector 70 formed at the lower portion of the mobile phone 12 are electrically connected. The first output terminal connection determination step, When the output terminal 85 of the mobile phone 12 and the interface connector 70 are electrically connected in the first output terminal connection determination step, the ambient temperature detected by the ambient temperature detecting means 92 is charged. A first charge lower limit temperature determining step for determining whether or not the lower limit temperature is lower than the lower limit temperature; A first charge upper limit temperature determination step of determining whether the ambient temperature detected by the ambient temperature detection means 92 is equal to or higher than the charge upper limit temperature when the charge lower limit temperature determination step is not lower than or equal to the charge lower limit temperature; In the first charge upper limit temperature determination step, when the charge upper limit temperature is not equal to or higher than the charge upper limit temperature, the charge current / voltage A / D values of the battery and the secondary battery 210 of the mobile phone 12 are determined by the first charge current / voltage detection means. A first charge current / voltage A / D value detection step detected at 83 and output to the microprocessor 81; After reading the charging current / voltage A / D values of the battery of the mobile phone 12 and the secondary battery 210 in the first charging current voltage A / D value detection step, the mobile phone 12 and After reading the charge current / voltage A / D value of the secondary battery 210 in the microprocessor 81, respectively, the charge current / voltage A / of the mobile phone 12 and the secondary battery 210. A first charging current / voltage A / D value VDD absolute value compensation step of compensating the D value in the A / D value VDD absolute value compensation means 94, After the first charging current / voltage A / D value VDD absolute value compensation step compensates for the VDD absolute value of the charging current / voltage A / D values of the mobile phone 12 and the secondary battery 210, the mobile phone A first limit current determination step of discriminating by the microprocessor 81 that has received the charging current flowing through the output terminal 85 whether the charging current of (12) is less than a limit current (400 mA); When the result of the determination in the first limit current determination step is less than the limit current, the microprocessor 81 subtracts the excess current obtained by subtracting the charging current of the mobile phone 12 from the charging limit current of the mobile phone 12. The excess current calculation step to calculate, The first charging current / voltage detecting means 83 detects whether the charging current of the mobile phone 12 is lower than a cut-off (CUT-OFF; 50 mA) current after calculating the excess current in the excess current calculating step. A first cut-off current discrimination step that is discriminated by the microprocessor 81 which has received a first charging current; A first phone charge voltage determination step of determining whether the charge voltage of the mobile phone 12 is greater than or equal to 3.9Vdc when the current of the mobile phone 12 is less than or equal to the cutoff current in the first cutoff current determination step; In the first phone charging voltage determination step, when the phone charging voltage is 3.9 Vdc or more, the microprocessor 81 sends an off control signal to the first switch 86 to turn off the battery charging of the mobile phone 12. A first phone charging end step of outputting and turning off battery charging of the mobile phone 12 and simultaneously emitting the dual type light emitting diode LED1 in green; After the battery charging of the mobile phone 12 is turned off at the first phone charging end step, the microprocessor 81 adds the internal total limit charging current (200 mA) and the spare phone charging current to the secondary battery ( A comprehensive limit charging current calculating step of calculating a comprehensive limit charging current for charging 210; The second charge current / voltage detecting means 87 detects whether the charge current of the secondary battery 210 is less than an internal comprehensive limit charge current after calculating the comprehensive limit charge current in the comprehensive limit charge current calculation step. An internal comprehensive limit charging current discrimination step discriminated by the microprocessor 81 which has received a second charging current, and The first secondary battery cut to determine whether the secondary battery cut-off current (50mA) or less when the charging current of the secondary battery 210 is less than the internal comprehensive limit charging current in the determination step of less than the internal comprehensive limit charging current. Off current discrimination step, When the secondary battery cut-off current determination step determines that the secondary battery cut-off current (50 mA) or less, the first 2 to determine whether or not the charge voltage of the secondary battery 210 is 3.9Vdc or more Battery charge determination step, As a result of the determination of the first secondary battery charge determination step, when the charge voltage of the secondary battery 210 is 3.9 Vdc or more, the microprocessor 81 may turn off the charge of the secondary battery 210. Outputting a control signal to the switch 89 to turn off the charge of the secondary battery 210, and at the same time to emit light of the dual-type LED (LED1) by the control signal output from the microprocessor (81) A charging control method for a portable charging device for a mobile phone, characterized by comprising a first secondary battery charging end step of turning off. The battery of the mobile phone 12 is the front housing 10 when the plug 200a of the travel adapter 200 is not connected to a power line. Receiving the signal detected by the output terminal 85 whether the charging terminal and the interface connector 70 formed in the lower portion of the mobile phone 12 are electrically connected to the receiving groove 14 formed in the A second charging terminal connection discrimination step judged by the processor 81, As a result of the determination of the second charging terminal connection discrimination step, when the charging terminal of the mobile phone 12 and the interface connector 70 are electrically connected, the ambient temperature detected by the ambient temperature detecting means 92 is A second charge lower limit temperature determining step for determining whether or not the charge lower limit temperature is lower; A second charge upper limit temperature determination step of determining whether the ambient temperature detected by the ambient temperature detection means 92 is equal to or higher than the charge upper limit temperature when the charge lower limit temperature determination step is not equal to or lower than the charge lower limit temperature; When the result of the determination of the second charge upper limit temperature determination step is not equal to or higher than the charge upper limit temperature, the secondary battery 210 is light-emitting to the green light while the dual type light emitting diode LED1 is turned off while charging the secondary battery 210. The secondary battery charging off step indicating that the battery is not being charged. The second charging current / voltage detecting means determines the charging current / voltage A / D value of the battery of the mobile phone 12 when the determination result of the secondary battery charging-off step is charging off the secondary battery 210. A second charging current / voltage A / D value reading step detected at 83 and output to the microprocessor 81; After reading the charging current / voltage A / D value of the battery of the mobile phone 12 at the second charging current / voltage A / D value detection step, respectively, in the microprocessor 81, the mobile phone 12 A second charging current / voltage A / D value VDD absolute value compensation step of compensating for the charging current / voltage A / D value of the A / D value VDD absolute value compensation means 94; After compensating the charging current / voltage A / D value of the mobile phone 12 in the second charging current / voltage A / D value VDD absolute value compensation step, the charging current of the mobile phone 12 is a limit current (400 mA). A second limit current determination step of determining by the microprocessor 81 whether it is less than or equal to; The microprocessor 81 determines whether the charging current of the mobile phone 12 is less than or equal to a cut-off (CUT-OFF; 50mA) current when the second limit current determination step determines that the current is less than the limit current. 2 cut-off current discrimination step, As a result of the determination of the second cut-off current determination step, when the current of the mobile phone 12 is less than or equal to the cut-off current, the second phone charging voltage determination to determine whether the charging voltage of the mobile phone 12 is 3.9 Vdc or more. Steps, As a result of the determination of the second phone charging voltage determination step, when the charging voltage of the mobile phone 12 is 3.9 Vdc or more, the microprocessor 81 may turn off the battery charging of the mobile phone 12. A second phone battery charge end step of outputting an off control signal to the switch 86 to turn off the battery charge of the mobile phone 12 and to turn off the green light emission of the dual type light emitting diode LED1. Charge control method of a mobile charging device for a mobile phone, characterized in that. The ambient temperature detecting means (92) according to claim 1, wherein when the charging terminal connection discrimination step is determined, when the charging terminal of the mobile phone (12) and the interface connector (70) are not electrically connected to each other, A third charge lower limit temperature determining step of determining whether the detected ambient temperature is lower than or equal to the charge lower limit temperature; As a result of the determination of the third charge lower limit temperature determination step, it is determined whether the ambient temperature detected by the ambient temperature detection means 92 is equal to or higher than the charge upper limit temperature when the charge lower limit temperature (-5 ° C) is not lower than or equal to. A third charge upper limit temperature determining step; As a result of the determination of the third charge upper limit temperature determination step, when the charge upper limit temperature is not higher than the charge upper limit temperature, the charging line of the battery of the mobile phone 12 is turned off and the green light of the dual type light emitting diode LED1 is turned off. A third mobile phone battery charge offstep of turning off, A third step of detecting the current voltage A / D value of the secondary battery 210 and outputting to the microprocessor 81 after charging the battery of the mobile phone 12 in a third mobile phone battery charging off step; Charge current voltage A / D value detection step, After the current voltage A / D value of the secondary battery 210 is read by the microprocessor 81 in the third charge current voltage A / D value detection step, the charge current / voltage of the secondary battery 210 is read. A third charging current / voltage A / D value VDD cut value compensation step of compensating an A / D value by the A / D value VDD absolute value compensation means 94; Whether the charging current of the secondary battery 210 is less than the limit current after compensating the current voltage A / D of the secondary battery 210 in the third charging current / voltage A / D value VDD absolute value compensation step A third limit current determination step of discriminating by the microprocessor 81 receiving the charging current detected by the second charging current / voltage detecting means 87; As a result of the determination of the third limit current determination step, when the charging current of the secondary battery 210 is not lower than the limit current (400 mA), the charging current of the secondary battery 210 is cut off (CUT). A third cut-off current discrimination step of discriminating by the microprocessor 81 that has received the second charging current detected by the second charging current / voltage detecting means 87 whether it is less than or equal to a current; A second secondary battery charging voltage determination step of determining whether the charging voltage of the secondary battery 210 is 3.9 Vdc or more when the determination result of the third cutoff current determination step is less than the cutoff current; As a result of the determination of the secondary battery charge voltage determination step, when the secondary battery 210 charge voltage is 3.9 Vdc or more, the microprocessor 81 may turn off the charge of the secondary battery 210. An off control signal is output to the second switch 86 to turn off the charging of the second secondary battery 210, and the dual type light emitting diode LED1 is controlled by the control signal output from the microprocessor 81. FIG. A charging control method for a mobile charging device for a mobile phone, characterized in that the second secondary battery charging end step is turned off. The microprocessor 81 according to any one of claims 1 to 3, wherein the charging current / voltage A / D value compensating step uses an absolute voltage (2.5Vdc) of the reference voltage set in the reference voltage setting means 93 in the microprocessor 81. The operating voltage of the microprocessor 81 is converted on the basis of the absolute value of the reference voltage read by the microprocessor 81 by reading with the relative value of the operating voltage of the microprocessor, and by the microprocessor 81 The charging control method of the mobile charging device for a mobile phone, characterized in that the compensation by multiplying the read current value / voltage A / D value by the operating voltage of the microprocessor 81 multiplied by the reference operating voltage (5V). delete