KR100383613B1 - Adapter having charging circuit - Google Patents

Abstract

PURPOSE: An adapter having a charging circuit is provided to reduce the manufacturing cost of the adapter by charging a rechargeable battery with a voltage converted to a lower voltage level in the adapter. CONSTITUTION: A voltage converter(26) is comprised of a voltage input unit(24), coils(28,30), and a rectifier(32). The voltage input unit(24) receives an AC(Alternating Current) voltage from an AC power source. The coils(28,30) receives the AC voltage through the voltage input unit(24) to convert it into a desired AC level. The rectifier(32) receives the converted AC voltage from the coils(28,30) and rectifies and converts it into a driving voltage of an electronic device. An adapter(22) includes a voltage output unit(44) for receiving the driving voltage converted from the voltage converter(26) to output it. A charger(46) is comprised of a constant current source(60), a rechargeable battery(62), and a charging device(58). The constant current source(60) and the rechargeable battery(62) receive the driving voltage from the voltage converter(26) to generate a constant current. The charging device(58) charges the rechargeable battery(62) with the constant current received from the constant current source(60).

Description

Adapter with built-in charging circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device for converting voltage in order to use an electronic device for driving a general household voltage at a low driving voltage, and more particularly, to an adapter.

General household voltage supplied to general households is AC 110V or 22OV. However, most commonly used electronic devices are driven at lower voltages than general household voltages. Therefore, in general, the adapter has been used to lower the general household voltage to the driving voltage of the electronic device.

Here, the adapter refers to an intermediate apparatus that adapts (fits) an apparatus or a component when they are different from each other. In general, the adapter has a function of converting an input voltage into a voltage desired by a user and outputting the same.

In the electronic device using the rechargeable battery, in order to charge the battery, the household voltage is first dropped using an adapter, and the voltage is applied to a charger having a built-in charging circuit to charge the rechargeable battery.

1 shows a conventional adapter block diagram.

The voltage input unit 10 receives a household voltage, that is, a voltage of AC 110V or 22OV and transmits it to the voltage converter 12. The voltage converter 12 converts the voltage applied from the voltage inputter 16 to a desired voltage, and applies the converted voltage to the voltage outputter 14. The voltage output unit 14 outputs the converted voltage.

2 is a block diagram of a conventional charger.

The voltage input unit 16 applies the input voltage to the charging device unit 18. The charging device unit 18 is equipped with a charging battery, and applies the voltage applied from the voltage input unit 16 to the charging battery. At this time, the rechargeable battery is charged by the voltage. In addition, the charging device unit 18 applies a signal indicating the state of charge of the rechargeable battery to the charging display unit 20, the charge display unit 20 indicates that the signal is being received from the charging device unit 18 is being charged.

In the prior art as described above, when using an electronic device using a rechargeable battery, there is a problem in that a charger having a separate voltage conversion adapter and a charging circuit is used.

Accordingly, an object of the present invention is to provide an adapter having a charging circuit for converting an input voltage and charging a rechargeable battery.

In order to achieve the above object, the present invention includes an adapter for converting a high voltage into a low voltage and a charging circuit for charging a rechargeable battery in order to drive an electronic device requiring a low driving voltage with a general household power supply.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, it should be noted that like elements in the drawings represent like reference numerals wherever possible. In addition, many specific details are set forth in order to provide a more thorough understanding of the present invention, such as in the following description and the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

3 is an adapter incorporating a charging circuit according to a preferred embodiment of the present invention.

The adapter includes an adapter 22 and a charging unit 46.

The adapter unit 22 includes a voltage input unit 24, a voltage converter 26, and a voltage output unit 44. The voltage converter 26 includes a primary coil 28, a secondary coil 30, a full wave rectifier 32, and a capacitor 42. The full wave rectifying unit 32 includes first ^to fourth diodes 34 ^to 40. The charging unit 46 includes a fifth diode 48, a switching unit 50, a charging device unit 58, and a charging display unit 64. The switching unit 50 includes a first resistor 52, a zener diode 54, and a first transistor 56. The charging device unit 58 is composed of a constant current source 60 and a charging battery 62. The charging display unit 64 includes a second resistor 66, a light emitting diode 68, and a second transistor 70. 4 (a), (b), (c) and (d) show the shape of the voltage at each part of the adapter.

When the AC voltage of the type shown in FIG. 4 (a) is applied to the voltage input unit 24 of the adapter unit 22, the voltage input unit 24 is connected to the primary coil 28 of the voltage conversion unit 26. Is applied. In the primary coil 28, the magnetic flux induced by the applied voltage is induced in the adjacent secondary coil 30. At this time, the voltage generated due to the magnetic flux induced in the secondary coil 30 is determined by the winding ratio of the primary coil 28 and the secondary coil 30. It is possible to generate the desired voltage as the turns ratio of the primary coil 28 and the secondary coil 30, which is generally recognized. The AC voltage generated in the secondary coil 30 is shown in the form as shown in FIG. 4 (b). The AC voltage generated in the secondary coil 30 is applied to the full-wave rectifier 32. The full-wave rectifier 32 uses a bridge rectifier that is commonly used, and the first ^to fourth diodes 34 ^to 40 are configured in the form of a bridge. The operation of the full wave rectifier 32 is as follows. During the half period of the positive (+) AC voltage generated in the secondary coil 30, the first diode 34 and the second diode 36 are conducted to generate a half cycle signal, and the AC generated in the secondary coil 30 During the negative half period of the voltage, the third diode 38 and the fourth diode 40 are conducted to generate another positive half period signal. At this time, the signal that is full-wave rectified and output is a pulsation voltage that increases from zero (0) to a peak and then decreases back to zero, as shown in FIG. However, the DC voltage needed for most electronic devices is not such a pulsating voltage. Therefore, in order to obtain a constant voltage, the capacitor 42 was filtered to obtain a signal as shown in the fourth (d). This signal is applied to the voltage output section 44, and the voltage output section 44 outputs the signal. The signal is applied to the charging unit 46 connected in parallel with the voltage output unit 44. The signal applied to the charging unit 46 is applied to the fifth diode 48 of the charging unit 46. The fifth diode 48 is turned on when a positive signal is applied from the adapter unit 22 to rectify the signal, and applies the signal to the charging unit 46. Therefore, the voltage of the charging section 46 when the voltage converted and inputted from the adapter section 22 is short-circuited at the output of the voltage output section 44 or the voltage converter section 42 of the adapter section 22 or is reversed. Reverse flow into the adapter portion 22 is prevented. The signal generated by the fifth diode 48 is applied to the switching unit 50 and the charging display unit 64. The zener diode 54 of the switching unit 50 is set to a voltage capable of charging the rechargeable battery 62. The zener diode 54 is a zener that is a voltage at which the rechargeable battery 62 can be charged when the signal input through the first resistor 52 is higher than the zener voltage set to a voltage capable of charging the rechargeable battery 62. Output voltage. Since the zener diode 54 is connected to the base terminal of the first transistor 56, the first transistor 56 is turned on by the zener voltage. Since the first transistor 56 is conductive, the voltage applied from the fifth diode 48 flows to the emitter terminal through the collector terminal of the first transistor 56. The signal output from the emitter terminal is applied to the constant current source 60 of the charging device unit 58. When the signal input through the zener diode 54 is lower than the zener voltage, the zener diode 54 is turned off so that the first transistor 56 is not conducted. Since the first transistor 56 is not conductive, current does not flow to the charging device unit 58.

The constant current source 60 of the charging device unit 58 is generated by receiving a current from the switching unit 50 and keeping the current constant. The charging battery 62 starts charging by the current applied from the constant current source 60, and when charging starts, a signal generated at the positive electrode of the charging battery 62 is applied to the second flange of the charging display unit 64. It is applied to the base terminal of the stud 70 to conduct the second transistor 70. The second resistor 66 of the charge display unit 64 receives a voltage from the fifth diode 48 and applies the voltage to the light emitting diode 68 by dropping the voltage, and the other terminal of the light emitting diode 68 Since the positive terminal of the rechargeable battery 62 is applied to the base terminal of the second transistor 70 and the second transistor 70 is turned on, the light emitting diode 68 is connected to the collector terminal of the second transistor 70. Indicates that the rechargeable battery 62 is being charged.

As described above, the present invention has the advantage of reducing costs and using space by charging a rechargeable battery with a voltage converted into a low voltage inside the adapter, compared to a separate product requiring a separate input device. .

In the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the equivalents of the claims and the claims.

1 is a block diagram of an adapter of the prior art.

2 is a block diagram of a charger of the prior art.

3 is a circuit diagram of an adapter incorporating a charging circuit according to the present invention.

4 (a) shows the waveform of the voltage applied to the adapter portion.

4 (b) shows the waveform of the voltage generated in the secondary coil of the adapter unit.

4 (c) shows the waveform of the voltage generated by the full-wave rectifier of the adapter unit.

4 (d) shows waveforms of voltages generated in the capacitor of the adapter unit.

Explanation of symbols for main parts of the drawings

22: adapter portion 24: voltage input portion

26: voltage converter 28: primary coil

30: secondary coil 32: full wave rectifier

34 ^to 40, 48: first ^to fifth diodes 42: condenser

44: voltage output section 46: charging section

50: switching unit 52, 66: first and second resistor

54: Zener Diodes 56, 70: First and Second Transistors

58: charging unit 60: constant current source

62: rechargeable battery 64: charge display unit

68: light emitting diode

Claims (5)

In the adapter with a built-in charging circuit for converting the AC voltage generated from the AC power supply to the drive voltage required for the electronic device to supply to the electronic device, and charging the rechargeable battery with the converted drive voltage, A voltage input unit for receiving an AC voltage from the AC power supply, a coil unit for receiving an AC voltage through the voltage input unit and converting the desired AC voltage, and receiving and rectifying the AC voltage converted from the coil unit A voltage converter having a rectifier for converting the driving voltage to An adapter unit including a voltage output unit for receiving and outputting a driving voltage converted by the voltage conversion unit; A charging circuit including a charging unit having a constant current source and a charging battery configured to receive a driving voltage from the voltage converting unit to generate a constant current, and a charging device unit configured to charge the rechargeable battery with the constant current applied from the constant current source. One adapter. The method of claim 1, wherein the rectifying unit, A full-wave rectifier for rectifying the AC voltage; And a filtering unit configured to filter the alternating current voltage rectified through the full-wave rectifying unit to direct-current voltage. The method of claim 1, wherein the charging unit, And a control unit connected between the voltage conversion unit and the constant current source to suppress reverse flow of current from the constant current source to the voltage output unit. The method of claim 1, wherein the charging unit, Connected between the voltage converter and the constant current source, and when the driving voltage applied from the voltage output unit is large enough to charge the rechargeable battery, a driving voltage is applied to the rechargeable battery, and the rechargeable battery is charged. The adapter having a charging circuit, characterized in that it further comprises a switching unit for controlling not to apply a voltage to the rechargeable battery if it is too small. The method of claim 1, wherein the charging unit, And a charging display unit configured to display a charging state by emitting a light emitting diode by receiving a high state signal generated during charging from the charging device unit.