KR100208990B1 - An apparatus for instantaneously controlling a monitor of power-savings type - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an instantaneous control device for a power-saving monitor, and the device of the present invention regulates the duty cycle of a signal supplied by an on / off switching operation to generate a power supply voltage to supply a video amplifier, a deflection circuit, and a heater (SMPS). 10); The power saving mode control unit 20 controls the switching operation of the SMPS 10 to switch to the power saving mode when a low level power saving signal is input from the microcomputer, and to cancel the power saving mode when the high level power saving signal is input. In the power saving type monitor, the control unit 30 is configured to immediately output a low or high level power saving signal to the power saving mode control unit 20 according to a user's request. By turning on or off, it is effective to save power saving mode switching time, thereby reducing power consumption.

Description

Power control monitor momentary control

1 is a block diagram of a general power saving monitor.

2 is a circuit diagram of a typical power saving monitor.

3 is a block diagram of an instantaneous control device for a power saving monitor according to the present invention.

4 is a circuit diagram of an instantaneous control device for a power saving monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: SMPS 20: Power Save Mode Control

30: instantaneous control unit 31: power supply unit

32: detector 33: clock generator

34 switching driver 35 switching unit

PR: Photoresistor Rs: Overvoltage Sense Resistor

ZD: Zener Diode Q1: First Transistor

DFF: D-Flip Flop Q2: Second Transistor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power saving monitor, and more particularly, to an instantaneous control device of a power saving monitor in which a power saving mode is set or canceled at right angles at the request of an operator.

In general, a power-saving monitor means that if the user leaves the computer for a while without turning off the power while using the PC or if the user does not use the PC for a long time, the microcomputer built in the PC recognizes this and outputs a power saving signal. It is a product that is dropped on the screen, and unlike the previous power off, when the user wants to use it again, the previous screen is automatically displayed on the monitor immediately.

The power saving signal is controlled by the software in the computer's micom, and if there is no input on the keyboard for a predetermined time (usually 1 or 2 minutes), the power saving signal is automatically output from the microcomputer to reduce the power consumption of the monitor. It stops the circuit operation and drives only the required power of the power saving mode control circuit.

In this case, the power saving signal indicates a high level in the normal mode and a low level in the suspend mode. Accordingly, a voltage of 100 V is applied to the video amplifier in the normal mode, and a voltage of 30 V or less is applied in the suspend mode.

In general, the power-saving monitor is often implemented as a Display Power Management System (DPMS) according to the standards of the VESA.

FIG. 1 is a configuration diagram of a general power saving monitor. As shown in FIG. 1, a general power saving monitor generates a power supply voltage by adjusting a duty cycle of a signal supplied by an on / off switching operation to generate a video amplifier, a deflection circuit, and a heater. SMPS 10 for supplying to; When the low-level power saving signal is input from the microcomputer, the power saving mode control unit 20 controls the switching operation of the SMPS 10 to switch to the power saving mode.

2 is a circuit diagram of a general power-saving monitor. First, the SMPS 10 includes: a power input unit 11 to which commercial AC power is applied through a fuse; An input filter unit 12 which receives an AC voltage from the power input unit 11 and removes high frequency noise; A bridge diode 13 for rectifying the AC voltage input from the input filter unit 12; A voltage smoothing unit (14) for smoothing the DC voltage input from the bridge diode (13); A transformer 15 receiving the smoothed DC voltage from the voltage smoothing unit 14 and generating induced electromotive force; A power transistor (16) connected to the primary winding of the transformer (15); A control IC 17 for controlling PWM of the operation of the power transistor 16 according to the input feedback voltage V _fb ; A rectifier circuit (18) for rectifying the output of the transformer (15); The photo coupler 19 is optically coupled to the rectifier circuit 18 and detects a signal output from the rectifier circuit 18 and outputs the signal to the feedback terminal of the control IC 17.

Referring to FIG. 2, the operation of the SMPS 10 is described first. When 100 V or 220 V of commercial AC power is applied through the fuse from the power input unit 11, the line filter L1 of the input filter unit 12 and The X capacitor C1, the line filter L2, and the Y capacitors C2 and C3 remove noise introduced through the AC power by the resonance action of L · C.

In addition, the Y capacitors C2 and C3 and the line filter L2 of the input filter unit 12 have high-frequency noise generated while the bridge diode D1 13 and the control IC 17 are operating on the AC input line. Block outgoing

On the other hand, the AC voltage passing through the line filter (L1) and the Y capacitor (C2) is rectified in the bridge diode D1 (13) and smoothed in the smoothing capacitor (C4) through the inrush current prevention resistor (R1) to the DC voltage ( V _i ) and then applied to the primary coil of the transformer 15.

At the same time, the rectified voltage rectified by the bridge diode D1 13 is applied to the V _cc terminal of the control IC 17 through the resistor R _g to operate the control IC 17, and is output from the control IC 17. The power transistor 16 is turned on / off by a control signal.

That is, when the said direct current voltage (V _i) is applied, it is the power supply (Vcc) of the control IC (17) as the direct-current voltage (V _i) is charged in the capacitor (C5) has reached a start-up voltage, the control IC ( 17) is activated to generate a PWM control signal, and the power transistor 16 is turned on / off by this PWM control signal.

When the power transistor 16 maintains an on state for a predetermined time according to an oscillator cycle in the control IC 17 and then turns off, an induced electromotive force is induced from the primary winding of the transformer 15 to the secondary winding. Done.

Therefore, the transformer 15 outputs an AC voltage V _s required by the secondary winding by the PWM control signal.

By repeating the above operation, the AC voltage V _s output from the secondary winding of the transformer 15 is rectified back to the DC voltage _Vo through the rectifier circuit 18.

That is, the AC voltage V _s input to the rectifier circuit 18 is converted into a DC voltage V _o , usually 100 V by the rectifying diode D 2 and the smoothing capacitor C 6, thereby converting the video amplifier and the deflection circuit, It is supplied to the heater of the CRT to operate the circuit.

In addition, as shown in FIG. 2, the power saving mode control unit 20 has a base end receiving a power saving signal from a microcomputer, and a collector end thereof is connected to the output of the SMPS 10 through a zener diode D3. A first transistor (21) which is turned on and is turned on when the high level power saving signal is inputted to flow the power voltage output from the SMPS to ground; A base terminal is connected in parallel between the output terminal of the SMPS 10 and the collector terminal of the first transistor 21, the collector terminal is connected to the output terminal of the SMPS 10 through a diode D4, and the emitter terminal is grounded. When the low-level power saving signal is input to the first transistor 21, the first transistor 21 is turned off and at the same time a power supply voltage is applied to the base and turned on, so that the power supply voltage flows through the collector stage to the emitter stage. A second transistor 22 grounded; And a photo coupler 19 optically coupled between the output terminal of the SMPS 10 and the collector terminal of the second transistor 22 to output the sensed signal to the feedback terminal of the SMPS 10 control IC 17. Consists of

As shown in FIG. 2, the power supply voltage 100V supplied to the video amplifier is branched and applied to the power saving mode control unit 20.

Therefore, when a high level power saving signal is input from the microcomputer, the first transistor 11 is turned on, and the power supply voltage of 100 V is input to the collector terminal of the first transistor Q1 through the zener diode D3 to emit the emitter terminal. Flows to ground.

At this time, since the collector terminal of the first transistor Q1 and the base terminal of the second transistor Q2 are connected in parallel, the current passing through the zener diode D3 flows only toward the first transistor Q1 and the second transistor Since it flows only toward (Q1) and does not flow toward the second transistor Q2, the second transistor Q2 maintains a turn-off state.

However, when the low-level power saving signal is input, the first transistor Q1 is turned off, so that the voltage passing through the zener diode D3 does not flow toward the first transistor Q1 and the base terminal of the second transistor Q2 does not flow. Is applied.

Accordingly, the second transistor Q2 is turned on so that the 100V power supply voltage is input to the collector terminal of the second transistor Q2 through the diode D4 and flows to the emitter terminal to ground.

At this time, more current flows to the photo coupler 19 positioned between the output terminal of the SMPS 10 and the collector terminal of the second transistor 22, and the overcurrent is supplied to the feedback terminal of the SMPS control IC 17. V _fb ).

As a result, the feedback terminal V _fb of the control IC 17 rapidly increases, thereby reducing the on time of the power transistor 16 and outputting the transformer 15 to the transformer 15 so that the transformer 15 is smaller than 100V. Output voltage.

While the low level power saving signal is input from the micom, the process is repeated to drop below a constant power saving voltage level, that is, 30V or less.

That is, the power supply voltage output from the SMPS 10 is applied to each of the monitors. At this time, when a low level power saving signal is input from the microcomputer to the power saving mode control unit 20, the power saving mode control unit 20 controls the SMPS 10. Power supply voltage outputted from the SMPS 10 is dropped to 30 W or less and supplied to an audio amplifier, deflection circuit, and the like by controlling the switching operation.

However, in the conventional power saving type monitor, if there is no key input for a predetermined time (1, 2 minutes), the microcomputer recognizes this and outputs a power saving signal automatically. It is supposed to perform a function. Therefore, there is a problem that power is wasted as much as the predetermined time.

Accordingly, the present invention has been made to solve the above problems, and relates to an instantaneous control device of a power saving monitor in which the power saving function is immediately set and released according to a user's request.

The instantaneous control device of the monitor according to the present invention for achieving the above object, SMPS for supplying to the video amplifier, the bias circuit and the heater by generating a power supply voltage by adjusting the duty cycle of the signal supplied by the on / off switching operation Wow; In the power saving monitor having a power saving mode control unit for controlling the switching operation of the SMPS to enter the power saving mode when receiving a low-level power saving signal from the microcomputer, and to cancel the power saving mode when receiving a high-level power saving signal. The controller may include an instantaneous control unit that immediately outputs a low or high level power saving signal to the power saving mode control unit according to a user's request.

The instantaneous control unit may include a power supply unit supplying a predetermined voltage to an input terminal of the power saving mode control unit; A detector configured to detect a power saving setting and release request of the user; A clock generator for generating a clock pulse of one cycle when receiving the detection signal; A switching driver which continuously outputs only one driving signal having a high or low level until the next pulse is input when the clock pulse is input; And a switching unit connected in parallel between the power supply unit and the power saving mode control unit to switch on / off when the driving signal is input and ground the power voltage input from the power supply unit when switching on. .

That is, the present invention is to provide an instantaneous control unit that is configured to immediately turn on or off the power saving function in accordance with the operator's request in the power-saving monitor, thereby saving power saving mode switching time.

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

3 is a configuration diagram of an instantaneous control device for a power saving monitor according to the present invention, including an SMPS 10; In the power saving type monitor equipped with the power saving mode control unit 20, the instantaneous control unit 30 is configured.

4 is a circuit diagram of an instantaneous control device for a power saving monitor according to the present invention, wherein the instantaneous control unit 30 includes a power supply unit 31; Sensing unit 32; A clock generator 33; Switching driver 34; The switch part 35 is comprised.

Here, the sensing unit 32, one end is connected to the power supply, the photoresist (PR) that the resistance value is reduced by itself when a small amount of optical signal is input than the reference; An overvoltage sensing resistor R _s connected between the photo resistor PR and ground; And a cathode terminal is connected in parallel between the photoresist 22 and the overvoltage sensing resistor Re, and is configured as a zener diode ZD that is turned on when a predetermined voltage or more is applied thereto, and the clock generator 33 The base terminal is connected to the anode terminal of the zener diode ZD, the collector terminal is connected to the power supply unit 31, and the emitter terminal is grounded. When the driving voltage is applied to the base terminal, the power supply unit 31 is applied. It is composed of a first transistor (Q1) that is supplied to the power supply voltage from the () flows through the collector stage to the emitter stage.

In addition, the switching driver 34 has a CK terminal connected to the collector terminal of the first transistor Q1. The terminal is composed of a D-flip flop (DFF) connected to the D terminal, the switching unit 35, the base terminal is connected to the Q terminal of the D-flip flop (DFF), the collector terminal is It is connected in parallel between the power supply unit 31 and the power saving mode control unit 20, the emitter terminal is grounded, when the base terminal is applied with a driving voltage, the power voltage input from the power supply unit 31 through the collector terminal It consists of the 2nd transistor Q2 which flows into an emitter stage and is grounded.

Next will be described in detail the operation and effect of the present invention configured as described above.

In the apparatus of the present invention, as shown in FIG. 4, the power supply unit 31 is connected to the power saving signal input terminal of the power saving mode control unit 20 in parallel with the power saving signal output terminal of the microcomputer. Make sure that a power supply voltage of 5V is always applied. In other words, a high level signal is always input to the power saving signal input terminal of the power saving mode control unit 20 during normal operation.

Then, when the operator hands over the photo resistor PR attached to the outside of the monitor to switch to the power saving mode, the photo resistor PR receives a smaller amount of light signal than the reference and lowers its resistance value.

As the resistance of the photoresistor PR decreases, the voltage applied to the overvoltage resistor Rs becomes relatively large.

Accordingly, when the voltage applied to the overvoltage sensing resistor Rs becomes greater than the sum of the zener diode voltage and the V _BE voltage of the first transistor, the zener diode ZD is turned on and the base of the first transistor Q1 is turned on. However, current flows.

As the zener diode ZD is turned on, the first transistor Q1 is also turned on.

At this time, since the collector terminal of the first transistor Q1 is connected to the power supply unit 31 and the emitter terminal is grounded, it is supplied from the power supply unit 31 as the first transistor Q1 is turned on momentarily. The supplied supply voltage flows instantaneously through the collector stage to the emitter stage.

Accordingly, the first transistor is turned on / off and a pulse wave of one cycle is input to the CK terminal of the D-flip flop DFF.

At this time, the D terminal of the D-flip flop (DFF) The terminal output signal is fed back. For example, the low level signal is set to an initial value at the Q terminal of the D-flip-flop (DFF), Set the high level signal to the initial value at the terminal. The high level signal of the terminal is fed back to the D terminal.

Accordingly, when a clock is input to the CK terminal, a high level signal is output from the Q terminal. A low level signal is output to the terminal.

With the above Q terminal Since the output state of the terminal is maintained until the next clock is input, the high level signal is continuously applied to the base terminal of the second transistor Q2 until the next clock is input.

The collector terminal of the second transistor Q2 is connected to the power supply unit 31, and branched a signal line between the collector terminal of the second transistor Q2 and the power supply unit to between the microcomputer and the power saving mode control unit 20. Is connected to the signal line.

In addition, the emitter terminal of the second transistor Q2 is grounded, and as the second transistor Q2 is turned on, all of the power voltages supplied from the power supply unit 31 flow to the emitter terminal through the collector terminal. .

Accordingly, since the 0V voltage is continuously applied to the power saving mode control unit 20, the power saving mode control unit 20 switches to the power saving mode.

When the operator again covers the photoresistor PR to release the set power saving mode, the photoresist PR receives a smaller amount of optical signal than the reference value and lowers its resistance.

When the resistance of the photoresistor PR falls, the voltage across the overvoltage sensing resistor Rs becomes relatively large. When the voltage across the overvoltage sensing resistor Rs becomes relatively large, the zener diode ZD As turned on, the first transistor Q1 is also turned on.

At this time, as the first transistor Q1 is turned on momentarily, the power supply voltage supplied from the power supply unit 31 flows to the emitter stage through the collector stage, and thus the CK terminal of the D-flip flop DFF. The pulse wave of 1 cycle is input into it.

At this time, the D terminal of the D flip-flop Since the low level signal of the terminal is fed back, when the clock is applied to the CK terminal, the low level signal is output from the Q terminal. A high level signal is output to the terminal.

With the Q terminal Since the output state of the terminal is maintained until the next clock is input, the low level signal is continuously applied to the base terminal of the second transistor Q2 until the next clock is input.

Accordingly, as the second transistor Q2 is turned off, all of the power supply voltages supplied from the power supply unit 31 flow to the power saving mode control unit 20. That is, since the 5V voltage is continuously applied to the power saving mode controller 20, the power saving mode is released.

As described above, the present invention has the effect of saving the power saving mode switching time and reducing power consumption by setting or canceling the power saving function according to the operator's request.

Claims (2)

An SMPS 10 for supplying a video amplifier, a deflection circuit, and a heater by generating a power supply voltage by adjusting a duty cycle of a signal supplied by an on / off switching operation; A power saving mode control unit (20) for controlling the switching operation of the SMPS (10) to switch to a power saving mode when a low level power saving signal is input from a microcomputer, and releasing the power saving mode when a high level power saving signal is input; In the instantaneous control device of the power-saving monitor consisting of the instantaneous control section 30 that outputs a low or high level power saving signal to the power saving mode control section 20 at the request of the user, the instantaneous control section 30 is a constant voltage A power supply unit 31 for supplying the power to the input terminal of the power saving mode control unit 20; A detector 32 configured to detect a user's power saving setting and release request; A clock generator 33 generating a clock pulse of one cycle by the first transistor Q1 turned on by the output signal of the detector 32; CK terminal is connected to the clock generator 33, The terminal is composed of a D-flip-flop (DFF) interconnected with the D terminal. When a clock pulse is input from the clock generator 33, only one driving signal of a high or low level is continuously output until the next pulse is input. Switching drive unit 34 and; A second transistor Q2 is connected in parallel between the power supply unit 31 and the power saving mode control unit 20 and switched on / off when the driving signal is input, according to the output signal of the switching driver 34. The instantaneous control device of the power-saving monitor, characterized in that it is composed of a switching unit (35) for grounding the power voltage input from the power supply unit (31). According to claim 1, wherein the sensing unit 32 is one end is connected to the power supply, the photoresist (PR) that the resistance value is reduced by itself when a small amount of light signal is input than the reference; An overvoltage sensing resistor Rs connected between the photoresist PR and ground; The cathode stage is connected in parallel between the photoresist 22 and the over-voltage sensing resistor (Re), the instantaneous control of the power-saving monitor, characterized in that the Zener diode (ZD) is turned on when a predetermined voltage or more is applied Device.