KR20070002719A - Charger for portable electronic device - Google Patents

Abstract

A charger for a portable electronic device is provided to charge a portable electronic device irrespective of a contact position with a charger by automatically determining a polarity of a contact terminal of a portable electronic device. A charger for a portable electronic device includes a voltage converter(320), a rectifier(325), a power side electrode terminal unit(315), and a control unit(350). The voltage converter(320) converts and outputs a voltage of an AC power inputted from an external apparatus. The rectifier(325) receives the AC power outputted from the voltage converter(320) and rectifies into a DC power, and outputs the rectified DC power. The power side electrode terminal unit(315) has a plurality of electrode terminals arranged on a plane. The power side electrode terminal unit(315) is formed to contact with each electrode terminal of the portable electronic device. The control unit(350) detects a power side electrode terminal contacted with the electrode terminal of the portable electronic device, and switches to apply the DC power outputted from the rectifier(325) to the detected electrode terminal.

Description

Charger for mobile device {Charger for portable electronic device}

1 is a perspective view showing a state of use of the mobile phone charger according to the prior art,

2 is a view schematically showing the configuration of a charger for a mobile device according to the present invention;

3 is a top view of the charger of FIG. 2, and

Figure 4 is a perspective view showing a state of use of the charger for mobile devices according to the present invention.

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

200: mobile device group 300: charger

201 to 204: Load side electrode terminals 230, 330: Insulator

210: mobile device 301 to 314: power supply electrode terminal

315: electrode terminal of the power supply side 320: voltage converter

325: rectifier 350: control unit

351: controller 352: first mux

353: second mux 211: mobile phone

212: electric shaver 213: PDA

The present invention relates to a charger for a mobile device, and more particularly, using a single charger for charging a plurality of mobile devices of various sizes and shapes at the same time, regardless of the contact position and the polarity of the electrode terminal charger It is about.

Portable electronic devices such as mobile phones, laptops, PDAs, GPS, etc. are becoming smaller and more diverse with the development of electronic technology. The power supply of such a portable device is a portable rechargeable battery (Rechargeable Battery) is used so that the user can use while moving. In order to charge such a battery, a charging matrix for supplying energy to a battery of a portable device in connection with a general power source is required. Typically, the charging base and the storage battery are configured with separate contact terminals on the outside thereof, so that the two contact terminals are connected to each other to selectively charge the storage battery as necessary.

1 is a perspective view showing a state diagram of use of the mobile phone charger according to the prior art. As shown in the drawing, a charger 101 for charging a mobile phone battery includes a mobile phone 51 or a main body 103 into which a mobile phone battery 53 is inserted, and a cord 105 connecting AC power to the main body 103. It is composed of

Inserting the main body slot 107 for inserting the mobile phone 51 in a state where the battery 53 and the mobile phone 51 are coupled to the main body 103, and inserting the battery 53 in a state separated from the mobile phone 51. Battery slots 109 are formed on the front and rear surfaces, respectively. A charging circuit board (not shown) for charging the mobile phone battery 53 is mounted inside the main body 103.

In addition, the main body slot 107 and the battery slot 109 are provided with a plurality of charging terminals 111 protruding from the lower end thereof so as to contact the charging terminals (not shown) of the battery 53.

In addition, the cord 105 connected to the rear end of the main body 103 is provided with a plug 113 at an end thereof to apply AC power through the outlet 55.

As described above, mobile devices such as mobile phones have different sizes or shapes depending on the manufacturer or model, and thus require a dedicated charger. When a user replaces a mobile device, a user can purchase a dedicated charger and waste a considerable amount of resources. There is a problem.

In order to solve the problem of the charger according to the prior art, a universal charger capable of charging various types of portable devices has been developed, but in the case of such a charger, a charger is required to accurately contact the contact terminals of the portable device and the charger. There was a problem that the work such as adjusting the distance between the contact terminals of the should be accompanied.

On the other hand, US Patent No. 6,650, 088 proposes a method that can be charged even if the mobile device is not coupled to a specific position of the charger by widening the contact terminal of the charger to solve the above problems. However, even in the case of such a charging device, there is a problem that can not be charged at the same time by contacting a plurality of mobile devices of different polarity to the contact terminal of one charger.

An object of the present invention is to solve the above problems, it is possible to simultaneously charge a plurality of mobile devices of various sizes and shapes by using a single charger, regardless of the polarity and contact position of the contact terminal of the mobile device It is an object to provide a charger for this portable device.

A portable device charger according to the present invention includes a charger for a mobile device having at least two electrode terminals for receiving a DC power supply, the charger comprising: a voltage converter for transforming and outputting a voltage of an AC power input from the outside; A rectifier for receiving the AC power output from the voltage converter and rectifying the DC power to output the DC power; A power supply side electrode terminal portion having a plurality of electrode terminals disposed on a substantially planar surface, the portion of which is in contact with each electrode terminal of the mobile device; And a controller configured to detect a power supply side electrode terminal in contact with the electrode terminal of the portable device, and to switch the DC power output from the rectifier to be applied to the detected electrode terminal.

When the portable device is provided in plural numbers, the control unit preferably detects electrode terminals in contact with the electrode terminal pairs of the plurality of portable devices among the plurality of power supply side electrode terminals.

In addition, the control unit may determine whether the contact with the electrode terminal of the mobile device and the polarity by measuring the current or voltage between the plurality of power-side electrode terminals.

Preferably, the plurality of power supply side electrode terminals have a matrix array, and the control unit is connected to correspond to the columns of the plurality of power supply side electrode terminals to selectively switch the connected electrode terminal sequence; A second mux connected corresponding to the rows of the plurality of power supply electrode terminals to selectively switch the connected electrode terminal rows; And controlling a switching operation of the first and second mux to detect a power supply side electrode terminal in contact with an electrode terminal of the mobile device, wherein the first and second mux selectively selectively detect the direct current with the detected electrode terminal. And a controller for controlling the power to be applied.

Hereinafter, with reference to the accompanying drawings will be described in more detail with respect to the configuration and operation of the present invention.

2 is a view schematically showing the configuration of a charger for a mobile device according to the present invention. As shown, the mobile device 210 is provided with load-side electrode terminals 201 and 202 corresponding to the negative electrode and the positive electrode to receive DC power from the charger 300. The load side electrode terminals 201 and 202 are insulated from each other by the insulator 230, and can come into contact with the power supply side electrode terminal portion 315.

The power supply side electrode terminal portion 315 of the charger 300 is composed of a plurality of electrode terminals 301 to 314 arranged in a matrix substantially on a plane. The power supply side electrode terminals 301 to 314 may be disposed on a substantially flat surface, but the surface may have various geometric shapes that are not flat. At this time, the size of each of the power supply side electrode terminals 301 to 314 is preferably smaller than the distance between the electrode terminals 201 and 202 of the portable device 210.

First, the voltage converter 320 converts the voltage of the commercial AC power input to a low voltage and outputs it to the rectifier 325. The rectifier 325 rectifies the alternating voltage input from the voltage converter 320 into direct current and outputs the rectified voltage to the controller 350.

The control unit 350 controls the electrode terminal and the polarity of the power-side electrode terminals 301 to 314 that are in contact with the first load side electrode terminals 201 and 203 and the second load side electrode terminals 202 and 204 of the portable device group 200. The DC voltage of the detected polarity is applied to the detected electrode terminal. At this time, the control unit 350 applies an instantaneous voltage to each electrode terminal 301 to 314 of the power supply electrode terminal unit 315 in turn, and measures the resistance value between each electrode terminal based on the amount of current flowing between each electrode terminal. Detect the polarity. The controller 350 determines whether contact with the load-side electrode terminal groups 201, 202, 203, and 204 is performed based on the resistance value between the electrode terminals measured in this way.

As an example in which the controller 350 determines whether the electrode terminals 301 to 314 are in contact with each other and the polarity, the first load side electrode terminal 201 is a ground terminal and the second load side electrode terminal 202 is a positive electrode terminal. The control unit 350 sequentially applies instantaneous potentials between the power supply side electrode terminals 301 to 314 and measures the amount of energization. As a result of the measurement, the control unit 350 detects a small amount of energization when a momentary potential is applied to the fourth power supply electrode terminal 304 with respect to the first power supply electrode terminal 301, and a very large amount of current supply with respect to the opposite direction. Will be detected. Accordingly, the controller 350 detects the first power supply electrode terminal 301 and the fourth power supply electrode terminal 304 as ground terminals and positive electrode terminals that are in contact with the electrode terminals 201 and 202 of the mobile device 210, respectively. .

If another portable device is placed on the charger 300 while the charger 300 is charging one mobile device, the controller 350 may include the first load electrode terminal 203 and the second electrode lower electrode terminal 204. ), The ninth power supply side electrode terminal 309 and the twelfth power supply side electrode terminal 312 are detected.

The control unit 350 applies a predetermined DC potential to the second power supply side electrode terminal groups 304 and 309 with respect to the first power supply side electrode terminal groups 301 and 309 detected in the above manner.

Referring to FIG. 3, an operation of determining whether the power supply side electrode terminal unit 315 is in contact with each other and a polarity and selectively applying DC power will be described in detail with reference to FIG. 3.

3 is a plan view of the charger of FIG. As shown, in the embodiment of the present invention, a plurality of power supply side electrode terminals 301 to 314 having a rectangular shape are arranged in a matrix, but various geometrical arrangements of electrode terminals having various shapes are possible. The control unit 350 is connected to a first mux 352 connected to each of the electrode terminal strings of the power supply side electrode terminal unit 315 having a matrix array, and corresponding to each electrode terminal row of the power supply side electrode terminal unit 315. 2 mux 353, and a controller 351 for controlling the switching operation of the first mux 352 and the second mux 353.

The controller 351 outputs a control signal for controlling the switching operation of the first mux 352 and the second mux 353 to the first mux 352 and the second mux 353 to supply power to the electrode terminal unit 315. The resistance value between the respective electrode terminals of &lt; RTI ID = 0.0 &gt;) is measured, &lt; / RTI &gt; and whether the contact with the load side electrode terminal groups 201 to 204 and the polarity are determined based on the measured resistance value. Then, the controller 351 controls the switching operation of the first mux 352 and the second mux 353 to control the switching operation of the first mux 352 and the second mux 353. Apply DC power.

The resistance value measurement is performed periodically to re-examine the electrode terminal group to which DC power should be applied when the portable device 200 is removed or the position is changed.

4 is a perspective view showing a state of use of the charger of FIG. As shown, a plurality of portable devices (mobile phone 211, PDA 213, and electric shaver 212) are placed on the power supply electrode terminal portion 315 of the charger 300 regardless of the contact position and direction. At the same time charging is possible.

In the detailed description of the present invention, specific embodiments have been described, but for those skilled in the art that various modifications may be made without departing from the scope of the present invention, such modifications are defined in the appended claims. It is in range.

As described above, the present invention provides an effect of simultaneously charging a plurality of mobile devices of various sizes and shapes using a single charger.

In addition, as well as supplying power by automatically determining the polarity of the contact terminal of the mobile device, it provides an effect that can be charged regardless of the contact position with the charger.

Claims (4)

In the charger for a mobile device having an electrode terminal for receiving a DC power, A voltage converter for transforming and outputting a voltage of an AC power input from the outside; A rectifier for receiving the AC power output from the voltage converter and rectifying the DC power to output the DC power; A power supply side electrode terminal portion having a plurality of electrode terminals disposed on a substantially planar surface, the portion of which is in contact with each electrode terminal of the mobile device; And And a controller configured to detect a power supply side electrode terminal in contact with the electrode terminal of the portable device, and to switch the DC power output from the rectifier to be applied to the detected electrode terminal. The method of claim 1, The portable device is provided with a plurality of, wherein the control unit is a charger for a portable device, characterized in that for detecting the electrode terminal in contact with the electrode terminal pairs of the plurality of mobile devices from the plurality of power-side electrode terminals. The method of claim 1, The control unit is a charger for a portable device, characterized in that by measuring the current or voltage between the plurality of power supply electrode terminals to determine whether the contact with the electrode terminal and the polarity of the portable device. The method of claim 1, The plurality of power supply side electrode terminals have a matrix array, and the control unit is connected to correspond to the columns of the plurality of power supply side electrode terminals to selectively switch the connected electrode terminal arrays; A second mux connected corresponding to the rows of the plurality of power supply electrode terminals to selectively switch the connected electrode terminal rows; And The switching operation of the first and second mux is controlled to detect a power supply side electrode terminal in contact with an electrode terminal of the mobile device, and the first and second mux selectively selectively detect the DC terminal with the detected electrode terminal. The controller for controlling the mobile device to be applied; Charger for a mobile device comprising a.

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