KR20130044139A - Auto switching charger for rechargable battery - Google Patents

Abstract

PURPOSE: An automatic switching battery charger is provided to use a circuit which comprises a transistor and a resistance, thereby reducing manufacturing unit cost. CONSTITUTION: A first and second charging terminals(310,320) are connected to power terminals of a battery. A power supply unit supplies DC power to the battery. A switching unit(200) connects the positive polarity of the DC power to a positive charging terminal. The switching unit connects the negative polarity of the DC power to a negative charging terminal. An output voltage regulating unit transmits a control signal to the power supply unit. [Reference numerals] (211) 1P type; (221) 1N type; (231) 2N type; (241) 2P type; (310,310') First charging terminal(BAT1); (320,320') Second charging terminal(BAT2); (600) Charging display unit

Description

AUTO SWITCHING CHARGER FOR RECHARGABLE BATTERY}

The present invention relates to an auto switching battery charger, and more particularly, to an auto switching battery charger capable of charging a battery having various forms and various charging voltages with a single charger.

Currently, secondary batteries generally used include hexagonal stick type (hereinafter, simply referred to as 'stick type (SB)') or AA / AAA type (CB). In addition, as the secondary battery, various types of nickel cardium (NiCd) batteries, nickel hydrogen (NiMH) batteries, lithium ion (Li-Ion) batteries, and lithium polymer batteries are known.

The rechargeable secondary battery is generally a daily electronic product such as a digital camera, a camcorder, a cellular phone, or an industrial product, depending on the type of electronic product to be used. According to the shape and size are manufactured differently. Also in a battery of the same shape. Each battery has a different charging voltage and a charging voltage according to the type of electronic product in which the battery is used, such as a digital camera, a camcorder, a cellular phone, and the like.

That is, lithium-ion and lithium polymer batteries applied to electronic products such as digital cameras, camcorders, and smartphones have a charging voltage of 3.6 V or 7.2 V, and the size or shape of these batteries also varies depending on the manufacturer or product. Therefore, in order to charge the battery used in such electronic products, a separate battery charger must be provided for each battery.

In order to solve this problem, Korean Patent No. 10-2088932 (hereinafter referred to as 'prior art'), filed and registered by the present applicant, can charge various kinds of batteries having various forms and various charging voltages. A battery charger that can be described is described.

However, the battery charger described in the above-mentioned prior art is expensive to manufacture because the expensive microcomputer is used to charge the battery by judging the polarity of the charging terminal connected to the battery. It is a difficult reality to use.

The present invention has been proposed to solve the above-described problems, by using a circuit composed of a transistor and a resistor to determine the polarity of the charging terminal connected to the power terminal of the battery to determine the polarity corresponding to the corresponding charging terminal with each charging terminal It is a technical object of the present invention to provide an auto switching battery charger capable of applying and recognizing a charging voltage of a battery and outputting a DC power corresponding to the charging voltage.

According to an aspect of the present invention, there is provided an auto switching battery charger including: a battery mounting unit including a first charging terminal and a second charging terminal connected to power terminals of a battery; A power supply unit supplying DC power for charging the battery; The polarity of the charging terminals is determined using the power applied from the battery mounted to the battery mounting unit through the first charging terminal and the second charging terminal, and the + polarity of the DC power transmitted from the power supply unit is charged. A switching unit for connecting to a charging terminal of the terminals and connecting the polarity of the DC power supply to the charging terminal of the charging terminals; And an output voltage adjusting unit for transmitting a control signal to the power supply unit by recognizing a charging voltage of a battery mounted in the battery mounting unit, so that the power supply unit outputs the DC power corresponding to the charging voltage as an output voltage. It includes.

According to the present invention, since the polarity of the charging terminal to which the power terminal of the battery is connected using a circuit composed of a transistor and a resistor can be determined, the polarity corresponding to the corresponding charging terminal can be applied to each charging terminal, so that the manufacturing cost is low. This provides the effect of public availability.

In addition, the present invention automatically recognizes the charging voltage of the battery, and generates an output voltage corresponding to the charging voltage, thereby providing an effect that can be commonly applied to batteries having various types of charging voltage.

1 is an internal configuration diagram of an auto switching battery charger according to the present invention.
2 is a circuit diagram of an embodiment of a switching unit applied to an auto switching battery charger according to the present invention;
3 and 4 are exemplary diagrams for explaining an operation method of the switching unit constituting the auto switching battery charger according to the present invention.
5 and 6 are various external configuration of the auto switching battery charger according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, the internal configuration of the auto switching battery charger according to the present invention will be described in detail with reference to FIGS. 1 to 4. Next, the external configuration of the auto switching battery charger according to the present invention will be described in detail with reference to FIGS. 5 and 6. It is explained.

1 is an internal configuration diagram of an auto switching battery charger according to the present invention, Figure 2 is a circuit diagram of an embodiment of a switching unit applied to the auto switching battery charger according to the present invention. 3 and 4 are exemplary views for explaining a method of operating a switching unit constituting an auto switching battery charger according to the present invention.

As shown in FIGS. 1 and 2, the auto switching battery charger according to the present invention includes a battery mounting part in which a first charging terminal 310 and a second charging terminal 320 connected to power terminals of the battery are formed ( 300) using a power supply unit 100 for supplying DC power for charging the battery, the power applied from the battery mounted in the battery mounting unit 300 through the first charging terminal and the second charging terminal; The polarity of the charging terminal is determined, and the + polarity of the DC power transmitted from the power supply unit is connected to the + charging terminal of the charging terminals, and the-polarity of the DC power is connected to the-charging terminal of the charging terminals. The switching unit 200 to compare the feedback charging voltage transmitted from the battery through the battery mounting unit 500 with the reference voltage using the comparison result using the comparison unit And turned on by a charging voltage adjusting unit 400 for transmitting a control signal to the power supply unit and a power applied from the power supply unit so that the power supply unit outputs the DC power corresponding to the charging voltage as an output voltage. And a charge display unit 600 for indicating that the battery is being charged. The configurations as described above are mounted in a housing interior 700 as shown in FIGS. 5 and 6.

Since the charging voltage adjusting unit 400 and the comparing unit 500 perform a function of adjusting the output voltage of the power supply unit, they are collectively referred to as an output voltage adjusting unit.

First, the battery mounting part 300 is a part to which the battery to be charged is mounted, and has a first charging terminal 310 and a second charging terminal 320.

Positions of the first charging terminal 310 and the second charging terminal 320 may be variable.

The pair of charging terminals including the first charging terminal 310 and the second charging terminal 320 are formed in the battery mounting part so as to correspond to the power terminals formed in the AA / AAA type secondary battery (CB). Another pair of charging terminals comprising another first charging terminal and another second charging terminal may correspond to the power supply terminals formed in the stick type secondary battery SB so that the battery mounting unit ( 300).

Therefore, all types of batteries may be mounted and charged in the battery mounting unit 300 regardless of the size of the battery, the type of the battery, the spacing of the power terminals provided in the battery, and the like.

That is, the interval between the first charging terminal 310 and the second charging terminal 320 may vary depending on the distance of the power terminal provided in the battery. In addition, the first charging terminal 310 and the second charging terminal 320 may be mounted on the battery mounting portion in a form that can correspond to the AA / AAA type secondary battery (CB), the stick type secondary The battery mounting unit may be mounted to the battery mounting unit in a form that may correspond to the battery SB, and two pairs of charging terminals corresponding to each of the different types of secondary batteries may be mounted to the battery mounting unit.

Second, the power supply unit 100 supplies a DC power (output voltage) for charging the battery to the battery through the switching unit 200 and the battery mounting unit 300.

The power supply unit 100 uses a charging voltage generator 110 for changing an AC voltage applied from an external power supply device to a DC voltage and a constant current for charging using a DC voltage generated from the charging voltage generator 110. It may include a charging constant current generator 120 for generating.

The power supply unit 100 may output a preset DC voltage (output voltage) to the switching unit 200 as it is, and when the control signal for changing the output voltage in the charging voltage adjusting unit 400 is changed. The output voltage may be changed by changing the level of the output voltage.

Power for driving the charging display unit 600 may be continuously transmitted to the charging display unit 600 through the switching unit 200.

Third, the switching unit 200, the power of the charging terminal using the power applied from the battery mounted to the battery mounting unit 300 via the first charging terminal 310 and the second charging terminal 320. It performs the function of judging polarity. In addition, the switching unit 200, the + polarity of the DC power transmitted from the power supply unit 100 of the first charging terminal 310 and the second charging terminal 320, the determination result + polarity Charging terminal (+ charging terminal) which is determined to have a negative polarity of the DC power supply, the first charging terminal and the second charging terminal of the determination result, the charging terminal is determined to have a polarity ( -To the charging terminal.

That is, in the state where the switching unit 200 is formed in the battery, of the two power terminals connected to the first charging terminal and the second charging terminal, which is a + power supply terminal and which is a -power supply Determine if it is a terminal. In addition, the switching unit 200 is applied from the power supply unit 100 to the + charging terminal that is determined to be connected to the + power terminal of the first charging terminal 310 and the second charging terminal 320. The + polarity is connected, and the -charge terminal, which is determined to be connected to the power supply terminal, is connected to the -polarity applied from the power supply unit 100.

To this end, the switching unit 200, as shown in Figure 2, the first switching device for applying the + polarity to the second charging terminal when the-polarity is applied from the first charging terminal 310. (210) When the + polarity is applied from the second charging terminal 320, the second switch 220 for applying the -polarity to the first charging terminal 310, + from the first charging terminal When the polarity is applied to the first charging terminal 310 when the polarity is applied from the third switch-230 and the second charging terminal 320 for applying the-polarity to the second charging terminal. And a fourth switcher 240 for applying the + polarity.

The first switcher 210 is turned on when -polarity is applied from the first charging terminal 310 so as to apply a first P-type transistor 211 to apply the + electrode to the second charging terminal 320. And the second switcher 220 is turned on when a positive polarity is applied from the second charging terminal 320 so as to apply the negative electrode to the first charging terminal 310. Including a 1N type transistor 221, the third switch 230 is turned on when the + polarity is applied from the first charging terminal 310, the -polarity to the second charging terminal 320 And a second N-type transistor 231 for applying a voltage, and the fourth switcher 240 is turned on when -polarity is applied from the second charging terminal 320, and thus the first charging terminal 310 is applied. A second P-type transistor 241 for applying the + polarity.

The first P-type transistor 211 is connected between the first power supply terminal 250 and the second charging terminal 320 to which the + polarity is applied, and the gate terminal of the first P-type transistor 211. Is connected to the first charging terminal 310. The first N-type transistor 221 is connected between the second power supply terminal 260 to which the -polarity is applied and the first charging terminal 310, and has a gate terminal of the first N-type transistor 221. Is connected to the second charging terminal 320. The second N-type transistor 231 is connected between the second power supply terminal 260 and the second charging terminal 320, and the gate terminal of the second N-type transistor 231 is charged in the first charging. It is connected to the terminal 310. The second P-type transistor 241 is connected between the first power supply terminal 250 and the first charging terminal 310, and the gate terminal of the second P-type transistor 241 is connected to the second charging. It is connected to the terminal 320.

An operation method of the switching unit 200 will be described with reference to FIGS. 3 and 4 as follows.

3 for explaining an example of the operation method of the switching unit 200, the first charging terminal (BAT1) 310 is connected to the -power terminal of the battery, the second charging terminal (BAT2) 320 is This is the case connected to the battery + power terminal.

That is, when the first charging terminal (BAT1) 310 is connected to the negative power supply terminal of the battery, and the second charging terminal (BAT2) 320 is connected to the + power supply terminal of the battery, the gate terminal is connected to the first charging terminal ( The first P-type transistor 211 of the second N-type transistor 231 and the first P-type transistor 211 connected to the 310 is turned on, and the second P-type is connected to the second charging terminal 320. The first N-type transistor 221 of the transistor 241 and the first N-type transistor 221 is turned on.

Accordingly, as shown in FIG. 3, the + electrode applied from the first power supply terminal 250 is transferred to the second charging terminal BAT2 320 through the first P-type transistor 211 turned on. The + electrode transmitted to the second charging terminal 320 is applied to the + power supply terminal of the battery. In addition, the negative electrode applied from the second power supply terminal 260 is transmitted to the first charging terminal BAT1 310 through the turned-on first N-type transistor 221, and the first charging terminal 310. The negative electrode transmitted to) is applied to the negative power supply terminal of the battery.

That is, when the first charging terminal (BAT1) 310 is connected to the negative power supply terminal of the battery, and the second charging terminal (BAT2) 320 is connected to the positive power supply terminal of the battery, The first N-type transistor 221 is turned on to apply a negative polarity to the first charging terminal BAT1 310 and a positive polarity to the second charging terminal BAT2 320.

5 for explaining another example of the operation method of the switching unit 200, the first charging terminal (BAT1) is connected to the + power supply terminal of the battery, the second charging terminal (BAT2) is-power supply of the battery The case connected to the terminal is shown.

That is, when the first charging terminal BAT1 is connected to the + power terminal of the battery, and the second charging terminal BAT2 is connected to the − power terminal of the battery, the gate terminal is connected to the first charging terminal 310. The second P-type transistor 241 and the second P-type transistor 231, of which the second N-type transistor 231 and the first P-type transistor 211 are turned on and whose gate terminal is connected to the second charging terminal 320, are formed. The second P-type transistor 241 of the 1N-type transistor 221 is turned on.

Therefore, as shown in FIG. 4, the + electrode applied from the first power supply terminal 250 is transferred to the first charging terminal BAT2 310 through the turned-on second P-type transistor 241. The + electrode transmitted to the first charging terminal 310 is applied to the + power supply terminal of the battery. In addition, the negative electrode applied from the second power supply terminal 260 is transmitted to the second charging terminal BAT2 320 through the turned-on second N-type transistor 231, and the second charging terminal 320. The negative electrode transmitted to) is applied to the negative power supply terminal of the battery.

That is, when the first charging terminal (BAT1) 310 is connected to the + power supply terminal of the battery, and the second charging terminal (BAT2) 320 is connected to the − power supply terminal of the battery, The second N-type transistor 231 is turned on so that + polarity is applied to the first charging terminal BAT1 310 and −polarity is applied to the second charging terminal BAT2 320.

Fourth, the comparator 500 performs a function of comparing a charging voltage, which is fed back from the battery and transmitted from the battery, to the reference voltage. That is, the comparison unit 500 receives the voltages applied to the battery, for example, 3.6 V or 7.2 V, which is the charging voltage of the battery, from the battery mounting unit 300 and feedbacks the feedback voltage to the reference voltage. A function of determining a charging voltage of the battery may be performed.

Fifth, the charging voltage adjusting unit 400 transmits a control signal for adjusting the output voltage of the power supply unit 100 to the power supply unit 100 by using the information compared by the comparator 500. Do this.

The operation method of the comparing unit 500 and the charging voltage adjusting unit 400 as described above will be described in detail.

The auto switching battery charger according to the present invention charges a stick type secondary battery SB, which is a lithium ion battery or a lithium polymer battery, and in particular, a stick type secondary battery SB having a charging voltage of 3.6 V or 7.2 V. When the charging voltage of the power supply having a function of automatically recognizing the charging voltage, the output voltage of the power supply 100 may be set to 8.4V, the reference voltage of the comparator 500 is set to 3.6V Can be.

As a first example, when a battery having a charging voltage of 3.6V is mounted in the battery mounting unit 300, the charging voltage of 3.6V is fed back to the comparator 500.

When the charging voltage adjusting unit 400 is set to operate when the reference voltage 3.6V and the feedback charging voltage are the same, since the feedback charging voltage of 3.6V is applied as described above, the charging voltage adjusting unit 400 is applied. Transmits a control signal for changing the output voltage to the power supply unit 100.

When the control signal is transmitted from the charging voltage adjusting unit 400, the power supply unit 100 having an output voltage of 8.4 V changes the output voltage to 4.2 V and outputs the output voltage to the switching unit 200.

Through the above-described process, the switching unit 200 knows the polarity of each of the charging terminals 310 and 320, and outputs an output voltage of 4.2 V transmitted from the power supply unit 100 to the charging terminal. Output according to polarity.

Therefore, even if a stick type secondary battery that does not know the polarity and the charging voltage of the power supply terminal is mounted in the battery mounting unit 300, the battery charger according to the present invention may determine the power terminal polarity of the battery mounted in the battery mounting unit 300. The battery may automatically recognize that the charging voltage of the battery is 3.6V, and charge the battery to an output voltage of 4.2V.

As a second example, when a battery having a charging voltage of 7.2V is mounted in the battery mounting unit 300, the charging voltage of 7.2V is fed back to the comparator 500.

When the charging voltage adjusting unit 400 is set to operate when the reference voltage 3.6V and the feedback charging voltage are the same as described above, since the feedback charging voltage of 7.2V is applied, the charging voltage adjusting unit 400 is applied. Does not operate, and thus, the control signal is not transmitted to the power supply unit 100.

Since the control signal is not transmitted from the charging voltage adjusting unit 400, the power supply unit 100 having an output voltage of 8.4 V outputs an output voltage of 8.4 V to the switching unit 200 as it is. .

Through the above-described process, the switching unit 200 knows the polarity of each of the charging terminals 310 and 320 and outputs an output voltage of 8.4 V transmitted from the power supply unit 100 to the charging terminal. Output according to polarity.

Therefore, even if a stick type secondary battery that does not know the polarity and the charging voltage of the power supply terminal is mounted in the battery mounting unit 300, the battery charger according to the present invention may determine the power terminal polarity of the battery mounted in the battery mounting unit 300. The battery may automatically recognize that the charging voltage of the battery is 7.2V, and charge the battery to an output voltage of 8.4V.

Meanwhile, in the above description, the present invention has been described with an example of automatically recognizing a charging voltage of a stick type secondary battery of 3.6 V or 7.2 V. However, the comparison unit 500 and the charging voltage adjusting unit 400 are 3.6. In addition to V or 7.2V, the output voltage of the power supply unit 100 may be adjusted by recognizing various charging voltages. In addition, the comparison unit 500 and the charging voltage adjusting unit 400 may be configured to recognize the three or more charging voltages to adjust the output voltage of the charging voltage adjusting unit 400.

Since the charging voltage adjusting unit 400 and the comparator 500 performing the above functions perform the function of adjusting the output voltage of the power supply unit, they are collectively referred to as an output voltage adjusting unit.

Sixth, the charging display unit 600 is turned on by the power applied through the power supply unit 100 to display that the battery is being charged.

That is, the charging display unit may be configured as a lamp, and may indicate that charging is currently performed by emitting light by power applied from the power supply unit through the switching unit.

5 and 6 are various external configuration diagrams of the auto switching battery charger according to the present invention.

The power supply unit 100, the switching unit 200, the battery mounting unit 300, the charging voltage adjusting unit 400, the comparing unit 500, and the charging display unit 600 as described above are illustrated in FIGS. 5 and 6. It is mounted in the same housing 700.

As illustrated in FIGS. 5 and 6, the housing 700 may include a main body 710 in which at least one of an AA / AAA type secondary battery (CB) or a stick type secondary battery (SB) may be mounted and charged. And an opening and closing plate mounted on an upper portion of the main body 710 to stably close and fix the AA / AAA type secondary battery (CB) or stick type secondary battery (SB) of different shapes or lengths to the main body 710. 720.

As a first embodiment of the present invention, the main body 710 and the opening and closing plate 720, as shown in Figure 5, the first charging terminal for connecting to the first power supply terminal of the stick-type secondary battery (SB) ( 310) and a pair of charging terminals comprising a second charging terminal 320 connected to the second power supply terminal of the stick type secondary battery SB, and a first power supply of the AA / AAA type secondary battery CB. Another pair of charging terminals including a first charging terminal 310 'connected to a terminal and a second charging terminal 320' connected to a second power supply terminal of an AA / AAA type secondary battery CB; and Another pair of charging terminals including a first charging terminal 310 ″ and a second charging terminal 320 ″ connected to another AA / AAA type secondary battery CB may be provided. .

As a second embodiment of the present invention, the main body 710 and the opening and closing plate 720, as shown in Figure 6, the first charging terminal for connecting to the first power supply terminal of the stick-type secondary battery (SB) ( 310) and a pair of charging terminals comprising a second charging terminal 320 for connecting with a second power supply terminal of the stick type secondary battery SB, and a second connecting type secondary battery SB. Another pair of charging terminals composed of one charging terminal 310 ′ and a second charging terminal 320 ′ may be provided. The stick type secondary battery SB may be formed of a lithium ion battery, a lithium polymer battery, or the like.

That is, the main body 710 and the opening and closing plate 720 may be provided with various numbers of charging terminals as shown in FIGS. 2 to 6.

Here, the opening and closing plate 720 is fastened in a sliding manner to the main body 710 and is not shown in the drawing, but because it is elastically supported in the direction in which the opening and closing plate 720 is closed by a spring therein. The batteries of various sizes and shapes may be disposed between the opening and closing plate 720 and the main body 710 to be stably fixed.

In addition, since the positions of the first charging terminals 310 and 310 'and the second charging terminals 320 and 320' mounted on the main body 710 may vary on the main body, Even if a type of stick type secondary battery SB is disposed, the power terminal of the stick type secondary battery, the first charging terminal and the second charging terminal may be electrically connected.

In addition, since the first charging terminal and the second charging terminal are formed in each of the opening and closing plate 720 and the main body 710, the AA / AAA type secondary battery CB of any size and shape is formed. Even the power supply terminal may be electrically connected to the first charging terminal and the second charging terminal.

Particularly, in the case of the AA / AAA type secondary battery CB, since the + power terminal and the − power terminal may be visually distinguished, the first charge formed for the AA / AAA type secondary battery CB may be used. The terminal and the second charging terminal may also be set to have a positive polarity.

However, in the case of the stick type secondary battery SB, since the polarities of the power terminals formed thereon are not visually distinguished, these power terminals may be correctly connected to the first charging terminal and the second charging terminal corresponding to the polarity. Can't.

However, as described with reference to Figures 3 and 4, the auto switching battery charger according to the present invention, what is the polarity of the power terminal connected to the first charging terminal 310 and the second charging terminal 320. By judging, the polarity corresponding to the polarity can be applied to the charging terminal.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: power supply 200: switching unit
300: battery mounting unit 400: charging voltage adjustment unit
500: comparison unit 600: charge display unit
700: Housing

Claims (7)

A battery mounting part including a first charging terminal and a second charging terminal connected to power terminals of the battery;
A power supply unit supplying DC power for charging the battery;
The polarity of the charging terminals is determined using the power applied from the battery mounted to the battery mounting unit through the first charging terminal and the second charging terminal, and the + polarity of the DC power transmitted from the power supply unit is charged. A switching unit for connecting to a charging terminal of the terminals and connecting the polarity of the DC power supply to the charging terminal of the charging terminals; And
An output voltage adjusting unit for transmitting a control signal to the power supply unit by recognizing a charging voltage of a battery mounted in the battery mounting unit, so that the power supply unit outputs the DC power corresponding to the charging voltage as an output voltage; Included auto switching battery charger. The method of claim 1,
The switching unit includes:
A first switcher for applying the + polarity to the second charging terminal when -polarity is applied from the first charging terminal;
A second switcher for applying the -polarity to the first charging terminal when + polarity is applied from the second charging terminal;
A third switcher for applying the -polarity to the second charging terminal when + polarity is applied from the first charging terminal; And
And a fourth switcher for applying the + polarity to the first charging terminal when -polarity is applied from the second charging terminal. 3. The method of claim 2,
The first switcher may include a first P-type transistor that is turned on when -polarity is applied from the first charging terminal to apply the + electrode to the second charging terminal.
The second switcher may include a first N-type transistor that is turned on when + polarity is applied from the second charging terminal to apply the − electrode to the first charging terminal.
The third switcher may include a second N-type transistor that is turned on when + polarity is applied from the first charging terminal to apply the −polarity to the second charging terminal.
And the fourth switch is turned on when -polarity is applied from the second charging terminal, and includes a second P-type transistor for applying the + polarity to the first charging terminal. The method of claim 3, wherein
The first P-type transistor is connected between the first power supply terminal to which the + polarity is applied and the second charging terminal, and the gate terminal of the first P-type transistor is connected to the first charging terminal,
The first N-type transistor is connected between the second power supply terminal to which the -polarity is applied and the first charging terminal, and the gate terminal of the first N-type transistor is connected to the second charging terminal,
The second N-type transistor is connected between the second power supply terminal and the second charging terminal, and the gate terminal of the second N-type transistor is connected to the first charging terminal.
And the second P-type transistor is connected between the first power supply terminal and the first charging terminal, and the gate terminal of the second P-type transistor is connected to the second charging terminal. charger. The method of claim 1,
Auto switching battery charger, characterized in that the position of the first charging terminal and the second charging terminal can be varied. The method of claim 1,
The pair of charging terminals including the first charging terminal and the second charging terminal are formed in the battery mounting part so as to correspond to the power terminals formed in the AA / AAA type secondary battery (CB),
Another pair of charging terminals composed of the first charging terminal and the second charging terminal is formed in the battery mounting portion so as to correspond to the power terminals formed in the stick type secondary battery SB. Auto switching battery charger. 7. The method according to any one of claims 1 to 6,
The output voltage adjusting unit,
A comparison unit for comparing the charging voltage fed back from the battery mounting unit with a reference voltage; And
According to the information compared in the comparison unit, the power supply including a charge voltage adjusting unit for transmitting a control signal for outputting the DC power corresponding to the charging voltage as an output voltage to the power supply unit; Switching battery charger.

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