KR100804742B1 - Apparatus for cutting down an electronic power in an electronic equipment - Google Patents

Abstract

An apparatus for cutting down standby power in electronic equipment is provided to reduce power consumption in a standby mode by supplying a driving voltage to a remote controller receiving unit and a microcomputer and intercepting alternating current power from being inputted. An apparatus for cutting down standby power in electronic equipment includes a first switching unit(200), a first voltage supplying unit(210), a second voltage supplying unit(220), a remote controller receiving unit(230), a microcomputer(240), a second switching unit(250), a second transformer(260), and first, second, and third diodes(D1.D2,D3). The microcomputer provides an on or off signal for turning on or off the actuation of the electronic equipment. The microcomputer applies the on-signal for turning the actuation of the electronic equipment and applies the off-signal for turning off the actuation of the electronic equipment to the first switching unit.

Description

Apparatus for reducing standby power consumption of electronic devices {APPARATUS FOR CUTTING DOWN AN ELECTRONIC POWER IN AN ELECTRONIC EQUIPMENT}

1 is a circuit diagram showing a conventional savings device for reducing standby power consumption.

2 is a circuit diagram illustrating a saving device for reducing standby power consumption according to the present invention.

<Description of the code | symbol about the principal part of drawing>

200: first switching unit 210: first voltage supply unit

220: second voltage supply unit 230: remote control receiver

240: microcomputer 250: second switching unit

260: second transformer

The present invention relates to an electronic device, and more particularly, to an apparatus for reducing standby power consumption of the electronic device.

Recent advances in analog and digital technology have created tremendous energy problems as electronics with advanced features rapidly spread into our homes and workplaces.

In particular, when the household appliances such as televisions, DVD players, etc. in everyday life is not used in the standby state, enormous standby power consumption of 3.25 trillion won per year is consumed.

In other words, the remote controller of home appliances, which are currently being used in homes, is mainly composed of remote control products that provide memory functions such as time and operation reservation, and the user must repeatedly plug and unplug the power supply every time the user recognizes a waste of power. Because of the inconvenience, most home appliances are always plugged into a power outlet even when the device is not in use.

Hereinafter, a conventional energy saving device for reducing standby power consumption will be described with reference to the accompanying drawings.

1 is a circuit diagram illustrating a saving apparatus for reducing conventional standby power consumption.

Referring to FIG. 1, the reduction device includes a rectifying unit 10 that receives an AC power source AC and converts it into a DC power source, and a transformer 20 that receives and transforms a DC voltage input from the rectifying unit 10. The diode D connected to the secondary side of the transformer 20 and the diode D are connected in parallel to charge the voltage output from the secondary side of the transformer 20 to control the remote controller receiver 30 and the microcomputer 40. The oscillation of the transformer 20 by receiving the feedback of the capacitor C for supplying the driving voltage Vcc to the feedback unit, the feedback unit 50 sensing the voltage output from the capacitor C, and the voltage sensed by the feedback unit 50. And a PWM controller 60 for outputting a PWM signal for controlling the operation.

The feedback unit 50 detects a signal according to the power on / off of the microcomputer 40 and a voltage output from the capacitor C, and outputs a predetermined feedback signal to the PWM controller 60. That is, the feedback unit 50 is supplied with a PWM signal having a predetermined period in a mode (standby mode) for supplying a predetermined driving voltage Vcc from the remote control receiver 30 and the microcomputer 40 in a power off state. The feedback signal for controlling the PWM controller 60 is generated.

Here, the PWM controller 60 supplies a PWM signal having a predetermined period, that is, a PWM signal turned on / off at a 100ms period in the standby mode, to the primary side of the transformer 20 according to the feedback signal provided from the feedback unit 50. .

Accordingly, the transformer 20 operates on or off at 100 ms periods, that is, the voltage input from the rectifier 10 is applied to the primary side in 100 ms periods, transformed to a predetermined voltage, and output through the secondary side. The diode D is driven on by the voltage output through the secondary side to charge the capacitor C, and the voltage charged in the capacitor C is stored in the remote controller receiver 30 and the microcomputer 40. It is used as the driving voltage Vcc.

Through this operation, even when the power of the electronic device is turned off, the remote control receiver 30 may receive a user's request (remote control signal) by receiving a predetermined driving voltage Vcc.

As described above, when a predetermined driving voltage is supplied to the remote controller receiver 30 and the microcomputer 40 in the standby mode, standby power is consumed by about 1 W to 3 W. In order to reduce the standby power, each consumer may not use the electronic device. Each time there is an inconvenience to unplug the electronic device.

An object of the present invention is to solve the problems of the prior art, by using the second voltage supply which is a battery such as a mercury battery in the standby mode, supplying a drive voltage to the remote control receiver and the microcomputer and cut off the incoming AC power. The present invention provides an apparatus for reducing standby power consumption of an electronic device that can reduce power consumption in a standby mode.

In order to achieve the above object, the present invention provides a device for reducing standby power consumption of an electronic device that requires the remote control reception standby operation, and provides a microcomputer for providing a low or high signal for turning on or off the driving of the electronic device; The first switching unit is turned on or off by a low or high signal output from the microcomputer, and is converted into a DC voltage by receiving AC power in a normal mode, and then converting the DC voltage into a voltage required for driving the microcomputer and the remote control receiver. A first voltage supply unit configured to output an output voltage, a second switching unit configured to apply or cut off AC power to the first voltage supply unit by being turned on or off according to an on or off operation of the first switching unit, and connected to the first switching unit And a second voltage supply supplying a driving voltage to the remote control receiver and the microcomputer in the standby mode. It includes parts.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram illustrating a saving device for reducing standby power consumption according to the present invention, wherein the first switching unit 200, the first voltage supply unit 210, the second voltage supply unit 220, and the remote control receiver 230 are shown. ), The microcomputer 240, the second switching unit 250, the second transformer 260, and the first, second, and third diodes D1, D2, and D3.

The microcomputer 240 provides an on or off signal for turning on or off the driving of the electronic device, and the on signal for turning on the driving of the electronic device (normal mode) as a predetermined signal is received from the remote controller receiver 230. (Low signal) is applied to the first switching unit 200, and otherwise (off standby mode), an off signal (high signal) for turning off the driving of the electronic device is applied to the first switching unit 200.

The first switching unit 200 is connected in parallel with the second voltage supply unit 220 receives a voltage from the second voltage supply unit 220, in particular, the second switching unit 250 according to the signal applied from the microcomputer 240. Control the operation of That is, the first switching unit 200 is turned off according to the high signal applied from the microcomputer 240 in the standby mode to block the voltage applied from the second voltage supplying unit 220 to the second switching unit 250. Turn off the operation of the second switching unit 250, and in the normal mode, the second switching unit 250 is turned on according to the low signal applied from the microcomputer 240 to supply the voltage applied from the second voltage supply unit 220 to the second switching unit 250. It is provided to turn on the operation of the second switching unit (250).

The first voltage supply unit 210 converts the AC power supplied to the DC voltage when the second switching unit 250 is turned on (normal mode), and then drives the microcomputer 240 and the remote controller receiver 240. Convert it to the voltage needed to output it.

The first voltage supply unit 210 includes a rectifier 212 that receives AC power and converts it into a DC power source, and outputs a transformer, and a transformer 214 that receives and transforms a DC voltage input from the rectifier 212. , The diode D connected to the secondary side of the transformer 214 and the diode D connected in parallel to charge the voltage output from the secondary side of the transformer 214 to control the remote controller receiver 230 and the microcomputer 240. The oscillation of the transformer 214 is fed back to the capacitor C for supplying the driving voltage Vcc to the feedback, the feedback unit 216 for sensing the voltage output from the capacitor C, and the voltage sensed by the feedback unit 216. And a PWM controller 218 for outputting a PWM signal for controlling the operation.

Here, the first voltage supply unit 210 applies a voltage of 6V to the remote control receiver 230 and the microcomputer 240 through the second and third diodes D2 and D3.

The second voltage supply unit 220 is connected to the first switching unit 200 to control the on or off operation of the second switching unit 250 through the first switching unit 200, and in the standby mode, the first diode ( The driving voltage Vcc is supplied to the remote controller receiver 230 and the microcomputer 240 through D1).

Here, the second voltage supply unit 220 is a means for supplying a DC voltage (5V) like a mercury battery, and is connected in parallel with the first switching unit 200, the remote control receiver 230, and the microcomputer 240.

The voltage supplied from the second voltage supply unit 220 to the second switching unit 250 is converted into a predetermined voltage by the second transformer 260 and supplied to the second switching unit 250.

The first diode D1 is applied with a voltage from the second voltage supply unit 220 at one end, a voltage is applied from the first voltage supply unit 210 at the other end, and according to an on operation of the second switching unit 250. When a voltage of 6 V is applied from the first voltage supply unit 210, the voltage of the second voltage supply unit 220 is blocked from being applied to the remote controller receiver 230 and the microcomputer 240 by the potential difference.

The second and third diodes D2 and D3 are connected in parallel so that one end of the second and third diodes D2 and D3 are connected to the remote controller receiver 230 and the microcomputer 240, respectively, and a voltage output from the second voltage supply unit 220 is applied, and the other end of the second and third diodes D2 and D3 is connected in parallel. The voltages output from the voltage supply unit 210 are applied to block the voltages supplied from the first voltage supply unit to the remote controller receiver 230 and the microcomputer 240 in the standby mode, respectively.

The operation of the energy saving device for reducing standby power consumption having the above configuration will be described below.

First, in the standby mode, the microcomputer 240 outputs a high signal to the first switching unit 200 as a power off signal, and the first switching unit 200 operates in response to the high signal.

The operation of the second switching unit 250 is turned off by blocking the voltage of the second voltage supplying unit 220 from being supplied to the second switching unit 250 according to the off operation of the first switching unit 200.

Accordingly, the AC power source AC can be blocked from flowing into the electronic device.

On the other hand, since the second voltage supply unit 220 supplies the driving voltage Vcc to the remote controller 230 and the microcomputer 240 connected in parallel, the remote controller 230 and the microcomputer 240 in the standby mode is the second The driving voltage may be always supplied by the voltage supply unit 220.

At this time, a voltage of 5V is applied to one end of the second and third diodes D2 from the second voltage supply unit 220, and a voltage of 0V is applied to the other end because no AC power is supplied to the first voltage supply unit 210. Thus, the voltage applied from the first voltage supply unit 210 is blocked from being supplied to the remote controller receiver 230 and the microcomputer 240.

When the electronic device operates in the normal mode, the microcomputer 240 outputs a low signal to the first switching unit 200 as a power-on signal, and the first switching unit 200 operates on in response to the low signal.

As the voltage of the second voltage supply unit 220 is supplied to the second switching unit 250 according to the on operation of the first switching unit 200, the operation of the second switching unit 250 is turned on.

Accordingly, AC power (AC) is introduced into the electronic device, that is, the first voltage supply unit 210 receives the AC power to supply the supply voltage required for driving the remote control receiver 230 and the microcomputer 240.

On the other hand, the voltage supplied from the second voltage supply unit 220 is cut off by the first diode (D1), that is, a voltage of 5V from the second voltage supply unit 220 is applied to one end of the first diode (D1), Since a voltage of 6 V supplied from the first voltage supply unit 210 is applied to the other end, the voltage of the second voltage supply unit 220 is transmitted to the remote controller receiver 230 and the microcomputer 240 by the potential difference of the first diode D1. By blocking the supply, the lifespan of the second voltage supply unit 220 may be extended.

According to the present invention, by supplying a driving voltage to the remote control receiver 230 and the microcomputer 240 by using the second voltage supply unit 220 in the standby mode, by blocking the introduction of AC power, the power consumption in the standby mode is reduced Can be.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the present invention provides a driving voltage to the remote controller receiving unit and the microcomputer using a second voltage supply unit, such as a mercury battery in the standby mode, and cuts off the AC power, thereby reducing power consumption in the standby mode. have.

Claims (5)

delete As a device for reducing standby power consumption of an electronic device requiring a remote control reception standby operation, A microcomputer providing a low or high signal to turn on or off the driving of the electronic device; A first switching unit turned on or off by a low or high signal output from the microcomputer; A first voltage supply unit configured to receive AC power in a normal mode, convert the DC voltage into DC voltage, and convert the AC voltage into a voltage required for driving the microcomputer and the remote controller; A second switching unit configured to apply or cut off AC power to the first voltage supply unit by turning on or off according to an on or off operation of the first switching unit; A second voltage supply unit connected to the first switching unit and supplying a driving voltage to the remote controller receiving unit and the microcomputer in a standby mode; The second voltage is connected between the second voltage supply unit and the remote control receiver, and a voltage output from the first voltage supply unit is applied at one end and a voltage output from the second voltage supply unit is applied at the other end to the second voltage in the normal mode. Breaker to cut off the voltage output from the supply Standby power consumption reduction device of the electronic device including a. The method of claim 2, The blocking unit is a standby power consumption saving device of the electronic device, characterized in that the diode to cut off the voltage applied from the second voltage supply in the normal mode. delete As a device for reducing standby power consumption of an electronic device requiring a remote control reception standby operation, A microcomputer providing a low or high signal to turn on or off the driving of the electronic device; A first switching unit turned on or off by a low or high signal output from the microcomputer; A first voltage supply unit configured to receive AC power in a normal mode, convert the DC voltage into DC voltage, and convert the AC voltage into a voltage required for driving the microcomputer and the remote controller; A second switching unit configured to apply or cut off AC power to the first voltage supply unit by turning on or off according to an on or off operation of the first switching unit; A second voltage supply unit connected to the first switching unit and supplying a driving voltage to the remote controller receiving unit and the microcomputer in a standby mode; Connected in parallel, one end of which is connected to the remote control receiver and the microcomputer, and a voltage output from the second voltage supply unit is applied, and a voltage output from the first voltage supply unit is applied to the other end, respectively, in the standby mode. Diodes for blocking the voltage supplied from the voltage supply unit to the remote control receiver and the microcomputer, respectively Apparatus for reducing standby power consumption of an electronic device comprising a.

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