KR20030034486A - Apparatus for terminal charge non- contact electromagnetic induction - Google Patents

Abstract

PURPOSE: An electromagnetic induction non-contact terminal charger is provided to be capable of utilizing an electromagnetic induction operation between a charger and a terminal. CONSTITUTION: A charger(100A) receives an AC power and supplies a power via a primary coil part(110A) by an electromagnetic induction manner. A terminal(200A) receives the AC power supplied from the charger(100A) via a secondary coil part(210A) and converts a DC power, which is supplied to a battery(230A). A rectification circuit part(220A) rectifies an AC power from the secondary coil part(210A), converts the rectified power into the DC power, and supplies the DC power to the battery(230A).

Description

Electromagnetic Induction Non-Contact Terminal Charging Device {APPARATUS FOR TERMINAL CHARGE NON- CONTACT ELECTROMAGNETIC INDUCTION}

The present invention relates to an electromagnetic induction contactless terminal charging device, and more particularly, to an electromagnetic induction contactless terminal charging device that can be charged by supplying the power of the charger to the terminal in a non-contact manner using electromagnetic induction.

In general, the mechanical contact charging device of the terminal is a charger and the terminal directly charges and charges, and is a charging device for supplying a charging voltage to the battery of the terminal through the contacting charging terminal, which will be described with reference to the accompanying drawings.

Figure 1 is a block diagram showing a mechanical contact charging device of the conventional terminal, as shown therein receives the AC power (AC) and then converts to a DC power and outputting the charger 100, the charger 100 It consists of a terminal 200 that is in contact with and receives the DC power output from the charger 100 to charge the battery.

The charger 100 receives the AC power AC to step down and outputs the coil unit 110 and the AC power AC output from the coil unit 110 to bridge diodes D1, D2, D3, and D4. The rectifier circuit unit 120, which is smoothed through the capacitor C1 and outputs the DC power, and the DC power output from the rectifier circuit unit 120 are contacted with the terminal 200. It is composed of a mechanical switch 130 to supply to (200).

Referring to the operation of the conventional terminal mechanical contact charging device configured as described above are as follows.

When AC power AC is inputted, the AC power AC is stepped down through the coil unit 110 and input to the rectifier circuit unit 120. The AC power AC input to the rectifier circuit unit 120 is a bridge diode. Full-wave rectified through D1, D2, D3, and D4, smoothed through the capacitor C1, and a direct current power source is applied to the mechanical switch unit 130.

Therefore, at this time, as the power input terminal of the terminal 200 is mechanically coupled to the mechanical switch unit 130, the DC power output from the rectifying circuit unit 120 is connected to the terminal 200 through the mechanical switch unit 130. ) Is charged to the battery.

However, in the above conventional technology, the mechanical coupling of the terminal 200 and the charger 100 is not properly performed, or the elderly and disabled people who are inconvenient to operate the mechanical coupling of the charger 100 and the terminal 200 well. There was a problem that does not occur.

In addition, the mechanical coupling between the terminal 200 and the charger 100 is not properly performed, there is a problem that occurs when the consumer is mistaken for a failure to apply for after-sales service.

Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide an electromagnetic induction contactless terminal charging device using an electromagnetic induction action between a charger and a terminal.

1 is a block diagram showing the configuration of a mechanical contact charging apparatus of a conventional terminal.

Figure 2 is a block diagram showing the configuration of the electromagnetic induction non-contact terminal charging device according to the present invention.

** Explanation of symbols for the main parts of the drawings **

100A: Charger 200A: Terminal

110A: winding type primary coil part 210A: winding type secondary coil part

The charger receives AC power and supplies the electromagnetic power through the winding type primary coil part, and AC power supplied by the electromagnetic induction method from the charger is stepped down through the winding type secondary coil part and converted into DC power. Characterized in that the terminal is configured to charge the battery.

The terminal is characterized in that it comprises a rectifier circuit unit for full-wave rectifying and smoothing the AC power inputted through the winding-type secondary coil part converted to DC power, and then supplied to the battery to charge.

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

Figure 2 is a block diagram showing the configuration of the electromagnetic induction non-contact terminal charging device according to the present invention, as shown in the AC power supply (AC) is supplied through the winding type primary coil portion (110A) as an electromagnetic induction method And a terminal 200A for receiving a step-down input through the winding-type secondary coil part 210A and converting the AC power supplied from the charger 100A into DC power to charge the battery 230A. .

The terminal 200A includes a winding type primary coil part 110A of the charger 100A, a winding type secondary coil part 210A for receiving a step-down input of AC power by acting electromagnetic induction, and the winding type secondary coil part. The AC power output from 210A is rectified, smoothed, and converted to DC power, and the rectifier circuit 220A is supplied to the battery 230A and charged.

The operation of the electromagnetic induction contactless terminal charging device configured as described above will be described.

When the AC power source AC is input, the AC power source AC is inputted to the wound primary coil part 110A, and the AC power source AC input to the wound primary coil part 110A is the terminal 200A. The winding-type secondary coil portion 210A of the step-down output by the electromagnetic induction action.

As described above, the AC power output through the electromagnetic induction action of the winding-type secondary coil unit 210A of the terminal 200A is full-wave rectified through the bridge diodes D1, D2, D3, and D4, and through the capacitor C1. It is smoothed and converted to DC power.

As described above, the DC power converted and output from the rectifying circuit unit 220A is input to the battery 230A and charged.

As described in detail above, the present invention can be provided by the non-contact power supplied from the charger in the terminal to charge, when the position of the terminal to the charger for charging, the selection of the charging position can be broken to provide more convenience to the user. In addition, it is possible to accurately perform the battery charging of the terminal, and there is no part in contact with the outside of the terminal has the effect of helping to develop a terminal and a charger, such as waterproof.

Claims (2)

The charger receives AC power and supplies the electromagnetic power through the winding type primary coil part, and AC power supplied by the electromagnetic induction method from the charger is stepped down through the winding type secondary coil part and converted into DC power. Electromagnetic induction contactless terminal charging device, characterized in that consisting of a terminal for charging the battery. The terminal of claim 1, wherein the terminal comprises a rectifying circuit unit for full-wave rectifying and smoothing the AC power inputted through the winding-type secondary coil unit, converting the AC power into a DC power, and supplying and charging the battery. Electromagnetic inductive contactless terminal charger.