KR20120070953A - Apparatus and method for reducing standby power of remote controller - Google Patents

Abstract

PURPOSE: Apparatus and method for reducing standby power of remote controller are provided to minimize standby power of a remote controller by providing standby power to a receive unit of a remote controller. CONSTITUTION: A power standby unit(40) stops operations at power standby mode. A charge unit(120) charges power through the power standby unit and applies operation power to a remote receiver at power standby mode. A charge controller(110) turns on the power standby unit and charges the charge unit.

Description

Apparatus and method for reducing standby power of a remote control device {APPARATUS AND METHOD FOR REDUCING STANDBY POWER OF REMOTE CONTROLLER}

The present invention relates to a standby power saving device and a control method of a remote control device for controlling the charging unit through the charging control unit, and supplying standby power to the remote control receiver of the remote control device through the charging unit.

In general, the first of the traditional configuration of a power control device in the home appliance field is to adopt a power supply unit (mainly a switching power supply unit) as a standby power supply unit and Most of the functional circuits are powered off, but use existing control and signal detection circuits (eg, single chip microcomputers and infrared signal receiving circuits) to control the standby power supply.

Secondly, it employs an auxiliary AC power supply unit (linear power supply unit or switching power supply unit) as a standby power supply unit, and with existing control and detection circuits (for example, single-chip microcomputer and infrared signal reception circuit). Control the standby power supply coupled or coupled with a separate standby power supply unit.

In this configuration, the external power is always supplied to the standby power supply unit, and the standby power is continuously applied from the standby power supply unit to the home appliance. There was a problem of consumption.

An object of the present invention is to control the charging unit through the charging control unit, supplying standby power to the remote control receiver of the remote control device through the charging unit to minimize the consumption of standby power consumed in the standby mode of the remote control device, The purpose is to provide a standby power saving device and control method.

The standby power saving apparatus of the remote control apparatus according to the present invention for achieving the above object is driven according to the power-on signal input from the outside so that the input power is supplied to the lower device, the operation is performed in the power standby mode Standby standby power unit; A charging unit which charges power supplied through the standby power unit according to a predetermined control signal and applies operating power to a remote control receiver in a power standby mode; And a charging control unit configured to turn on the standby power unit to charge the charging unit when the power of the charging unit is discharged more than a predetermined time in the standby mode state.

The control method according to the present invention for achieving the above object, the first step of applying the power of the charging unit in the standby mode to the remote control receiver of the remote control device; A second step in which a charging control unit connected to the charging unit measures the charging amount of the charging unit, and charges the charging unit with power of the standby power supply unit; A third step of applying external power applied to the remote controller by operating the standby power unit when a power-on signal is externally input to the standby power unit; And a fourth step of stopping the operation of the standby power supply unit when a power-off signal is applied to the standby power supply unit, and supplying standby power to the remote controller through the transformer by the control signal of the charging control unit. It is done.

According to the standby power saving device and control method of the remote control device according to the present invention configured as described above, the charging control unit controls the charging and discharging of the charging unit, the charging unit after stopping the driving of the standby power unit according to the charging amount of the charging unit Since the standby power is applied to the remote control receiver through, there is an advantage of minimizing the power consumed during the standby mode of the remote control device.

1 is an overall configuration diagram of a standby power control apparatus according to an embodiment of the present invention.
2 is a view showing the operation of the charging unit according to the driving time of the remote control device according to an embodiment of the present invention.
3 is a flowchart illustrating a standby power control method according to the present invention.
4 is an operation flowchart of a standby power control method according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. Like elements in the figures are denoted by the same reference numerals wherever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

Here, the remote control device refers to devices capable of remote control, such as television, DVD player, audio, air conditioning.

The remote control receiver may use a telecommunication method such as RF, IR, ZigBee, Bluetooth, RFID, or the like.

1 is an overall configuration diagram of a standby power control apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the present invention includes a rectifier 10, a power factor correction control unit 20, a power factor improvement unit 30, a power supply unit 50, a standby power supply unit 40, and a charge control unit 110. ), The charging unit 120, the transformer 130 and the like.

The rectifier 10 includes a bridge diode and a capacitor to rectify and output power input from the outside.

The power factor correction control unit 20 is connected to the power factor improvement unit 30, and the power factor improvement unit 30 always outputs power at a constant output level from the external power rectified by the rectifier 10.

The power factor improving unit 30 includes an inductor 31 having one end connected to the rectifying unit 10 and a rectifier diode 32 connected in a forward direction between an output terminal of the inductor 31 and the power factor improving unit 30. And a main switch 33 connected between the connection node of the inductor 31 and the rectifier diode 32 and the ground and switched through a control signal.

The power factor correction control unit 20 switches the main switch 33 of the power factor improving unit 30, and switches the main switch 33 to a frequency higher than a frequency of an input signal, and the main switch 33. Adjust the on-time of) to be proportional to the magnitude of the input voltage. Accordingly, the current flowing through the inductor 31 is controlled by the amount of current according to the switching period of the power factor correction controller 20 to compensate for the power factor.

The power factor correction control unit 20 measures and monitors the output voltage by the standby power supply unit 40 and the power supply unit 50, and performs a latch operation when an overvoltage is output from the output terminal.

In this case, the main switch 33 may be a field effect transistor (FET) or a bipolar transistor.

As described above, when the overvoltage is output through the output terminal, the power factor correction controller 20 detects the overvoltage through the standby power supply unit 40 and the power applying unit 50 to perform the latch operation in the power factor correction controller 20. have. That is, the power factor correction control unit 20 receives the output voltage through the standby power supply unit 40 and the power supply unit 50 and detects the output voltage. When the detected voltage is an overvoltage higher than the set voltage, the latch operation is performed to output the overvoltage. Do not

However, when there is an abnormality in the power factor compensation control unit 20 or the feedback terminal, and the overvoltage cannot be detected through the standby power supply unit 40 and the power supply unit 50, the power factor compensation control unit 20 continuously By switching the main switch 33, the output voltage continuously increases, thereby damaging the peripheral components of the output terminal.

In fact, if the voltage at the output stage rises above 450V, the components around the output stage may explode.

The standby power supply unit 40 is operated through a signal applied from the power factor correction control unit 20 or the rectifier 10.

In addition, the standby power unit 40 is a power applied from the outside to apply power in the operation mode to the remote control receiver.

At this time, when the power of the remote controller is turned off in the standby mode (standby state), the charging unit 120 instead of the standby power unit 40 applies the standby power required to maintain the standby mode to the remote control receiver.

The charging control unit 110 is driven by the power applied from the standby power unit 40, and controls whether the standby power unit 40 is driven and the charging of the charging unit 120 connected to the lower.

In this case, the charging unit 120 is connected to the charging control unit 110 to charge and discharge through the control signal of the charging control unit 110.

When the remote controller receiver is switched to the standby mode according to the power on / off signal input to the standby power unit 40, the charging control unit 110 applies the standby power to the charging unit 120 instead of the standby power unit 40. To prevent the standby power supply unit 40 from operating.

However, when the charging amount of the charging unit 120 is 5% or less, the standby power unit is operated to charge the charging unit 120 through the charging control unit 110.

In this case, the charging unit 120 stops discharging and only charges, and applies power from the standby power unit to the remote control receiver.

When the charging amount of the charging unit 120 is 100% through the charging, standby power is applied to the remote control receiver instead of the standby power unit 40 without additional charging.

At the same time, the charging control unit 110 to stop the operation of the standby power unit 40.

When the charging amount of the charging unit 120 is less than 100%, the charging unit 120 is charged to 100% and then the power of the charging unit 120 is applied to the remote control receiver.

Here, the charging amount of the charging unit 120 may also be measured by the voltage output from the charging unit 120. When the output voltage of the charging unit 120 is 3V or less, the standby power unit 40 is the charging control unit 110. It is driven through the control signal of the charging unit 120 can be charged.

At the same time, power from the standby power source 40 may be applied to the remote control receiver.

When the voltage output from the charging unit 120 is 4.25V or more, the operation of the standby power unit 40 is stopped by the control signal of the charging control unit 110, and the power of the charging unit 120 is stopped by the remote control receiver. Can be sent to.

That is, when the power of the remote controller is turned off and in the standby mode, when the charging amount of the charging unit 120 is 0 to 99%, the charging unit 120 is charged by the power of the standby power unit and the power of the standby power unit 40 This is applied to the remote control receiver.

When the charging amount of the charging unit 120 is 100%, the driving of the standby power unit 40 is stopped, and the charging unit 120 applies standby power to the remote control receiver.

2 is a view showing the operation of the charging unit according to the driving time of the remote control device according to an embodiment of the present invention.

As shown in FIG. 2, when the remote controller is driven, the charging unit 120 is charged through a control signal of the charging control unit, and when the remote controller is not driven, the charging unit 120 discharges the remote control receiver. Standby power is applied to.

3 is a flowchart illustrating a standby power control method according to the present invention.

3, the standby power control method according to the present invention is as follows.

The first step (S100) of applying the power of the charging unit to the remote control receiver in the standby mode, and charging the charging unit 120 with a control signal of the charging control unit, and transforms the power discharged from the charging unit to the transformer 130 The second step (S200), the third step (S300) to operate the standby power unit when the power-on to apply to the remote control receiver of the remote control device, the standby power unit is stopped operating when the power off, and the power of the charging unit 120 And a fourth step S400 of supplying the remote control receiver.

The first step (S100) is a step of applying the power of the charging unit to the remote control receiver of the remote control device in the standby mode.

The second step (S200) is a step of measuring the charging amount of the charging unit 120 through the charging control unit 110 and charging the charging unit 120 with power applied from the standby power supply unit 40.

In this case, the charging control unit 110 is driven by the power applied from the standby power unit 40, and controls the charging of the charging unit 120 connected to the lower depending on whether the standby power unit 40 is driven.

The second step (S200) is the charging unit 120 by the power applied from the standby power unit 40 when the amount of charge of the charging unit 120 through the charge control unit 110 and the range of 0 to 99%. Will charge up to 100%.

When the charging amount of the charging unit 120 is 100%, the operation of the standby power unit 40 is stopped, and the charging unit 120 outputs the standby power to the remote control receiver through the transformer unit 130.

In addition, the voltage output from the charging unit 120 converts the voltage available from the transformer 130 into an available voltage available for the remote control unit, and applies the converted standby voltage to the remote control unit.

Here, the charging amount of the charging unit 120 may also be measured by the voltage output from the charging unit 120. When the output voltage of the charging unit 120 is 3V or less, the standby power unit 40 is the charging control unit 110. It is driven through the control signal of the charging unit 120 can be charged.

At the same time, power from the standby power source 40 may be applied to the remote control receiver.

When the voltage output from the charging unit 120 is 4.25V or more, the operation of the standby power unit 40 is stopped by the control signal of the charging control unit 110, and the power of the charging unit 120 is stopped by the remote control receiver. Can be sent to.

The third step S300 is a step of applying external power applied to the remote controller by operating the standby power unit 40 when a power-on signal is input to the standby power unit 40 from the outside.

At this time, in the third step S100, the external power rectified by the rectifier 10, the power factor correction controller 20, and the power factor improvement unit 30 to compensate for the power factor is the standby power source 40 and the power applying unit. Applied to the 50, the external power applied to the standby power unit 40 is applied to the charge control unit 110 to drive the charge control unit 110.

Here, the rectifier 10 includes a bridge diode and a capacitor to rectify and output power input from the outside.

In addition, the power factor correction control unit 20 is configured to be connected to the power factor improvement unit 30, the power factor improvement unit 30 is to always output power to a constant output level the external power rectified by the rectifier 10. do.

In this case, the power factor improving unit 30 is an inductor 31 connected to one end of the rectifier 10 and a rectifier diode 32 connected in a forward direction between an output terminal of the inductor 31 and the power factor improving unit 30. And a main switch 33 connected between the inductor 31 and the connection node of the rectifier diode 32 and the ground, and switched through a control signal.

The power factor correction control unit 20 switches the main switch 33 of the power factor improving unit 30, and switches the main switch 33 to a frequency higher than that of the input signal, and the main switch 33 of the main switch 33. Adjust the On-time to be proportional to the magnitude of the input voltage. Accordingly, the current flowing through the inductor 31 is controlled by the amount of current according to the switching period of the power factor correction controller 20 to compensate for the power factor.

The power factor correction control unit 20 measures and monitors the output voltage by the standby power supply unit and the power supply unit 50, and performs a latch operation when an overvoltage is output from the output terminal.

In this case, the main switch 33 may be a field effect transistor (FET) or a bipolar transistor.

As described above, when the overvoltage is output through the output terminal, the power factor compensation control unit 20 detects the overvoltage through the standby power supply unit 40 and the power supply unit 50 to perform a latch operation in the power factor compensation control unit 20. There is this.

That is, the power factor correction control unit 20 detects the output voltage through the standby power supply unit 40 and the power supply unit 50 by feedback and performs a latch operation when the detected voltage is an overvoltage greater than or equal to a set voltage. Do not

However, when there is an abnormality in the power factor compensation control unit 20 or the feedback terminal, and the overvoltage cannot be detected through the standby power supply unit 40 and the power supply unit 50, the power factor compensation control unit 20 continuously By switching the main switch 33, the output voltage continuously increases, thereby damaging the peripheral components of the output terminal.

In fact, if the voltage at the output stage rises above 450V, the components around the output stage may explode.

At this time, the external power is simultaneously applied to the standby power unit 40 and the power applying unit 50, and applied to the remote control receiver so that the remote control receiver can operate.

In the third step (S300), the standby power unit 40 measures the presence or absence of an external power on signal input, and when the power on signal is input from the outside, the standby power unit 40 is operated so that the charging control unit 110 Power is directly applied to the remote control receiver without going through.

At the same time, power is applied to the rectifier 10, the power factor correction control unit 20, the power factor improvement unit 30, and the power supply unit 50 to operate the remote controller.

When the power on signal is not applied from the outside, the standby power supply unit 40 stops the operation, and the standby power output from the charging unit 120 is applied to the remote control receiver.

In the fourth step S400, when a power-off signal is applied to the standby power unit 40, the operation of the standby power unit 40 is stopped, and the power is supplied from the charging unit 120 by the control signal of the charging control unit 110. The step of applying to the remote control device through the transformer.

In the fourth step S400, when a power off signal is externally applied to the standby power supply unit 40 to stop driving of the remote controller, the standby power supply unit 40 stops driving and simultaneously charges the charge. The charging unit 120 outputs power as a control signal of the controller 110.

Then, the power output from the charging unit 120 is transformed into a usable voltage available to the remote control receiver in the transformer 130 is applied to the remote control receiver.

However, if no power-off signal is input from the outside, the standby power supply unit 40 maintains the operation so that the remote control receiver continues to be driven.

In this process, the charging unit 120 is charged by measuring the amount of charge in the second step (S200).

When the standby power unit 40 is operated when an external power-on signal is input, the charging unit 120 charges the insufficient charge amount with the control signal of the charging control unit 110.

Subsequently, when the standby power unit 40 operates in the third step S300, the standby power unit is supplied to the charging unit as a control signal of the charging control unit 110 so that the insufficient amount of charge of the charging unit 120 occurs. Is charged.

That is, when the power of the remote controller is turned off and in the standby mode, the charging unit 120 is charged with the power of the standby power unit 40 when the charging amount of the charging unit 120 is 0 to 99%. At the same time, the power of the standby power unit 40 is applied to the remote control receiver.

In addition, when the charging amount of the charging unit 120 is 100%, the driving of the standby power unit 40 is stopped, and the charging unit 120 is output to apply standby power to the remote control receiver.

Here, the charging amount of the charging unit 120 may also be measured by the voltage output from the charging unit 120. When the output voltage of the charging unit 120 is 3V or less, the standby power unit 40 is the charging control unit 110. It is driven through the control signal of the charging unit 120 can be charged.

At the same time, power from the standby power source 40 may be applied to the remote control receiver.

When the voltage output from the charging unit 120 is 4.25V or more, the operation of the standby power unit 40 is stopped by the control signal of the charging control unit 110, and the power of the charging unit 120 is stopped by the remote control receiver. Can be sent to.

4 is an operation flowchart of a standby power control method according to an embodiment of the present invention.

Referring to FIG. 4, the external power is rectified through the rectifying unit 10 and supplied to the standby power supply unit 40 and the power supply unit 50 through the power factor improving unit 30 and the power factor correction control unit 20 (S100). ).

Then, the charging control unit 110 connected to the standby power unit 40 measures the charging amount of the charging unit 120 (S200), and if the charging amount of the charging unit 120 is 0 to 99%, the standby power unit 40 In operation S210, the charging unit 120 is charged through the power applied from the standby power unit 40 (S211).

At the same time, standby power is applied to the remote control receiver from the standby power supply 40 (S220).

Then, when the charging unit 120 is 100% charged, the operation of the standby power unit 40 is stopped by the control of the charging control unit 110, and the standby power discharged from the charging unit 120 is applied to the remote control receiver. Done.

When the charging amount of the charging unit 120 measured by the charging control unit 110 is 100%, the operation of the standby power unit 40 is stopped by the control of the charging control unit 110, and the charging unit 120 Standby power is discharged and applied to the remote control receiver (S221).

In this process, the charging amount of the charging unit 120 may also be measured by the voltage output from the charging unit 120. The charging unit 120 may be charged by being driven by the control signal of 110.

At the same time, power from the standby power source 40 may be applied to the remote control receiver.

When the voltage output from the charging unit 120 is 4.25V or more, the operation of the standby power unit 40 is stopped by the control signal of the charging control unit 110, and the power of the charging unit 120 is stopped by the remote control receiver. Can be sent to.

When the standby power is supplied from the outside to the remote control receiver while the standby power is supplied to the remote controller through the charging unit 120 (S300), the standby power unit 40 is operated (S310), and the standby power unit When the 40 is operated, the charging unit 120 is charged through the control of the charging control unit 110 (S311).

Then, the standby power supply unit 40 is operated at the same time the power factor correction control unit 20 and the power supply unit 50 is operated (S312) to output the operating power to drive the remote control device (S313).

However, when the standby power is not supplied from the outside to the remote controller while the standby power is supplied to the remote controller through the charging unit 120, the standby power unit 40, the power factor compensation controller 20, and the power applying unit are not input. Operation 50 continues to be stopped and power discharged from the charging unit 120 is applied to the remote control receiver.

When the power-on signal is input through the remote controller and the remote controller is driven, the power-off signal is input to the standby power unit 40 through the remote controller while the remote controller is driven. The driving of 50 is stopped (S400).

Thereafter, the standby power unit 40 stops the operation through the control signal of the charging control unit 110 (S410), and at the same time, the charging unit 120 applies standby power to the remote control receiver.

If the power-on signal is not input in the S300, the steps S200, S210, S211, S220, S221, S400, and S410 are repeated.

This is repeated until the power-on signal is input.

When the power-on signal is input at S300, the steps S300, S310, S311, S312 and S313 are repeated.

This is repeated until the power off signal is input.

The present invention configured as described above controls charging and discharging of the charging unit through the charging control unit, and stops driving of the standby power unit according to the charging amount of the charging unit, and thus, standby power is applied to the remote control receiver through the charging unit. There is an advantage of minimizing the power consumed.

The present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the similar scope should be interpreted as being included in the present invention.

10: rectifier 20: power factor correction control unit
30: power factor improvement unit 31: inductor
32: rectifier diode 33: main switch
40: standby power supply unit 50: power supply unit
110: charging control unit 120: charging unit
130: transformer

Claims (15)

A standby power source which is driven according to an externally input power on signal to supply input power to a lower device, and stops operation in a power standby mode;
A charging unit which charges the power supplied through the standby power unit according to a predetermined control signal and applies operating power to the remote controller receiving unit in the power standby mode; And
And a charging control unit configured to turn on the standby power unit to charge the charging unit when the power of the charging unit is discharged more than a predetermined time in the standby mode state.
The method of claim 1,
And a transformer unit connected to the charger unit and configured to convert the power applied from the charger unit into a required voltage and apply the transformer unit to the remote controller receiver.
The method of claim 2,
The transformer is a DC / DC converter for converting the voltage applied from the charging unit to the available to the remote control receiver available to the remote control receiver, standby power saving device of the remote control device.
The method of claim 1,
The charging control unit is connected to the standby power unit in the standby mode to charge the charging unit with the power output from the standby power unit, and stops the operation of the standby power unit when the charging of the charging unit is completed, standby power saving of the remote control device Device.
The method of claim 1,
The standby power unit stops the operation when the remote control device is in the standby mode, and continuously applies power to the remote control receiver when in the operation mode, standby power saving device of the remote control device.
The method of claim 1,
The charging unit is charged according to the control of the charging control unit, and when the remote control device in the standby mode, the power is continuously applied to the remote control receiver, standby power saving device of the remote control device.
A first step of applying the power of the charging unit to the remote control receiver in the standby mode;
A second step of charging a charging control unit connected to the charging unit to measure the charging amount of the charging unit, and charging the charging unit with power of the standby power supply unit;
A third step of, when the power-on signal is input to the standby power unit from the outside, operating the standby power unit to apply power applied from the outside to various circuit units;
And a fourth step of stopping the operation of the standby power supply unit when a power-off signal is applied to the standby power supply unit, and supplying power of the charging unit to the remote control receiver through a transformer by a control signal of the charging control unit. Standby power control method using the device standby power saving device.
8. The method of claim 7,
In the second step, when the charging amount is 0 to 99% by measuring the charging amount of the charging part through the charging control part, the charging power is charged through the standby power part, and at the same time, standby power is applied from the standby power part to the remote control receiver. And if the charging amount of the charging unit is 100%, applying standby power to the remote controller receiving unit through the control of the charging control unit and stopping the operation of the standby power unit at the same time.
8. The method of claim 7,
In the second step, the voltage output from the charging unit is converted into an available voltage available to the remote control receiver in the transformer unit, and applies the converted standby power to the remote controller receiver, using the standby power saving device of the remote control device. Power control method.
8. The method of claim 7,
In the third step, the external AC power is rectified to DC through the rectifier to be applied to the power factor correction control unit, the standby power unit and the power supply unit, and the power is supplied from the standby power unit to the charging control unit. Standby power control method using a device.
8. The method of claim 7,
In the third step, the presence or absence of an external power-on signal input from the standby power unit to the remote controller receiver is measured, and when the external power-on signal is input through the remote controller receiver, the standby power unit is operated to supply standby power to the remote controller receiver. Applied, standby power control method using the standby power saving device of the remote control device.
8. The method of claim 7,
In the fourth step, when a power-off signal is externally applied to the standby power supply unit to stop the operation of the remote controller, the standby power supply unit is stopped and power is supplied from the charging unit to the control signal of the charging control unit. And discharging the power discharged from the charging unit to the available voltage available from the transformer to the remote controller receiving unit, and applying the power to the remote controller receiving unit.
8. The method of claim 7,
The charging unit is charged by measuring the amount of charge in the second step, when the power-on signal is input from the remote control receiver in the third step and the standby power unit is operated through the control signal of the charge control unit to charge the insufficient charge of the charging unit The standby power control method using the standby power saving device of the remote control device.
8. The method of claim 7,
The third step is a standby power control method using a standby power saving device of a remote control device to stop the operation of the standby power unit when the external power on signal is not applied, and to apply standby power to the remote control receiver through the charging unit. .
8. The method of claim 7,
The fourth step is a standby power control method using a standby power saving device of a remote control device to maintain the operation of the standby power unit if the external power off signal is not received, the remote control receiver continues to drive.

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