KR0177940B1 - Power preganglionic circuit of monitor - Google Patents

Abstract

The present invention relates to a power saving power supply circuit for a monitor that can reduce unnecessary power loss by controlling the operation of the power supply unit in a power saving mode in the power supply circuit of the monitor.

In the power saving circuit of the conventional monitor, even though the power saving signal is applied from the microcomputer and the power saving mode is being executed, the power supply unit continues to operate, thus causing unnecessary power loss.

The present invention is to solve the above problems, in order to prevent unnecessary power loss by preventing the power supply unit does not operate in the power saving mode, to stop the operation of the power supply unit in the power saving mode, and to detect the horizontal synchronization signal and vertical synchronization signal The power supply unit is operated to prevent power consumption due to unnecessary operation of the power supply unit in the power saving mode to obtain a power saving effect, which is applied to a monitor power supply circuit of a computer.

Description

Power saving circuit of monitor

1 is a power saving circuit diagram of a conventional monitor.

2 is a power saving circuit diagram of the monitor of the present invention.

3 is a diagram of each sub waveform in the power saving circuit of the monitor of the present invention.

4 is a view showing an embodiment of an optical coupler in the power saving circuit of the monitor of the present invention.

(a) is an optical coupler incorporating a field effect transistor (FET).

(b) is an optical coupler incorporating a silicon controlled rectifier (SCR).

(c) is an optical coupler using a relay switch.

* Explanation of symbols for main parts of the drawings

2: constant voltage IC 4: voltage control IC

5: power control IC 6: horizontal synchronous signal detector

7: vertical synchronous signal detection unit 8: horizontal synchronous signal detection unit

PC1, PC2: Optical Coupler

The present invention relates to a power supply power saving circuit of a monitor to reduce unnecessary power loss by controlling the operation of the power supply unit in the power saving mode in the power supply circuit of the monitor.

As shown in FIG. 1, the power saving circuit of the conventional monitor includes a bridge diode BD1 for bridge rectifying the input AC power, and a transformer T1 for transforming the power rectified by the bridge diode BD1. By the power saving control unit (1) for controlling the power saving state by the power saving signal applied from the microcomputer, and by the transformer (T1) secondary side winding (NP4) by the power saving control signal output from the power saving control unit (1) A switching unit 3 for selectively switching a voltage output induced by the induced voltage and outputted by the secondary winding NP5 and maintained at 12 V by the constant voltage IC 2, and outputting to the microcomputer; A voltage control IC (4) for controlling the voltage (V1) induced and output by the transformer (T1) secondary winding (NP3) by changing the resistance value of the variable resistor (VR1) according to the control signal output from (1). ) And control output from the power saving control unit 1 Optocoupler PC1, which operates according to the signal and applies the voltage supplied to the microcomputer to the power supply control IC 4, and detects the voltage applied from the optocoupler PC1 to detect the primary winding of the transformer T1. It consists of a power supply control IC (5) for controlling the power applied to.

Reference numerals R1 to R5 denote resistors, C1 to C5 capacitors, D1 to D6 diodes, and VR1 are variable resistors.

When the power saving signal is input from the microcomputer of the power saving circuit of the conventional monitor having the above configuration, the power saving control unit 1 outputs a low signal to the switching unit 3 and the diode D6.

The switching unit 3 receiving the low signal from the power saving control unit 1 switches to the terminal 'a' and supplies the voltage V2 induced by the secondary winding NP4 of the transformer to the microcomputer.

In addition, the diode D6 is turned on to increase the voltage applied to the optical coupler PC1. As a result, the voltage output from the optical coupler PC1 is detected by the power supply control IC 5 so that the transformer T1 is turned on. Control the power applied to) to operate in the power saving state.

On the other hand, when the power saving signal is not applied from the microcomputer, the power saving control unit 1 outputs a high signal to the diode D6 and the switching unit 3.

When the high signal is outputted from the power saving control unit 1, the switching unit switches to the 'b' terminal side to convert the voltage induced by the secondary winding NP5 of the transformer T1 by the constant voltage IC 2. The voltage maintained at 12V is supplied to the microcomputer.

At this time, since the voltage applied to the optocoupler PC1 is lowered as the diode D6 receives the reverse voltage, the power control IC 5 supplies the power applied to the transformer T1 so that the power supply unit operates in a normal state. Control.

However, in the power-save circuit of the conventional monitor, even though the power-saving signal is applied from the microcomputer and the power-saving mode is being executed, the power-supply unit is operated, causing unnecessary power loss.

The present invention detects the horizontal synchronous signal and the vertical synchronous signal to control the operation state by using the horizontal synchronous signal and vertical synchronous signal in order to solve such a conventional problem, thereby preventing unnecessary power loss by preventing the power supply from operating in the power saving mode. It is intended that the same parts as those described above will be omitted by the same reference numerals.

The configuration of the power saving power circuit of the monitor of the present invention, as shown in Figure 2, receives the power saving signal, detects the voltage input from the power control IC (5) to control the power supply of the transformer (T1) to control the transformer (T1) In the power supply power saving circuit of the monitor that controls the secondary output voltage (V1, V2, V3) of

A horizontal synchronous signal detector 6 for detecting a horizontal start signal HS, a vertical synchronous signal detector 7 for detecting a vertical synchronous signal VS, and a horizontal synchronous signal detector 6 or a vertical synchronous signal detector ( The optical coupler PC2 which is initially driven by the signal voltage detected in 7) and then driven by the voltage applied by the transistor Q1 to supply the operating power to the power supply control IC 5, and the transformer T1. The microcomputer 8 for switching the transistor Q1 on and off by controlling whether the vertical synchronization signal HS or the horizontal synchronization signal VS is input by receiving the voltage V3 output from It is composed of a buffer transistor (Q1) for supplying a voltage of 12V applied to the optical coupler (PC2) by switching on / off under the control of.

By controlling the operation of the optical coupler (PC2) by using the horizontal synchronization signal (HS) and the vertical synchronization signal (VS) input from the computer of the power saving circuit of the monitor of the present invention configured as described above to control the operation of the power supply unit. In order to minimize the power consumption of the monitor in the power saving mode,

The input horizontal synchronous signal HS and the vertical synchronous signal VS are converted into DC signals through the horizontal synchronous signal detector 6 and the vertical synchronous signal detector 7.

As described above, when only one of the DC signal and the horizontal synchronous signal HS and the vertical synchronous signal VS is input, the optical coupler PC2 operates to supply power to the power control IC 5.

Referring to FIG. 3, the optical coupler PC2 will not operate unless both the horizontal synchronous signal HS and the vertical synchronous signal VS are input. Therefore, the power supply control IC 5 has no power supply. As it is not supplied, the power supply unit is not operated.

At this time, if any one of the horizontal synchronization signal HS or the vertical synchronization signal VS is inputted under the synchronization signal, the voltage at the point 'A' is gradually raised, as shown in (b) of FIG. When the above rises, the optocoupler PC2 operates to supply power to the power supply control IC 5.

When power is supplied to the power supply control IC 5, the power supply control IC 5 is operated, and the transformer T1 is operated to output the secondary side voltages V1, V2, and V3 of the transformer T1. Will be.

The secondary output voltage V3 12V of the transformer T1 is converted into a voltage V3 'of 5V through a regulator of the rear stage and supplied to the microcomputer 8.

Then, the microcomputer 8 receives a voltage of 5V, recognizes the input of the vertical synchronization signal HS and the horizontal synchronization signal VS, outputs a high signal as shown in (c) of FIG. 3, and provides the buffer transistor Q1. Is switched to ounce to supply a voltage of 12V applied to the collector terminal of the transistor Q1 to the optical coupler PC2.

From this time, the diodes D7 and D8 of the horizontal synchronous signal detector 6 and the vertical synchronous signal detector 7 are turned off, and the driving voltage of the optical coupler PC2 is applied to the 12V voltage applied through the buffer transistor Q1. This is used.

That is, the signal voltages output from the horizontal synchronous signal detector 6 and the vertical synchronous signal detector 7 are used only as the initial drive voltage of the optical coupler PC2.

Thereafter, when neither the horizontal synchronous signal HS nor the vertical synchronous signal VS is input, the microcomputer 8 outputs a low signal to turn off the transistor Q1 to turn off the operation of the optical coupler PC2. The power supplied to the power control IC 5 is cut off so that the power supply unit does not operate.

That is, the power supply unit does not operate in the power saving mode.

On the other hand, as shown in (a) (b) and (c) of FIG. 4 of the optical coupler PC2 used above, an optical coupler and a silicon controlled rectifier (SCR) incorporating a field effect transistor (FET) The built-in optical coupler and relay switch may be used.

As described above, the power supply unit is stopped in the power saving mode, and the power supply unit is operated by detecting the horizontal synchronization signal and the vertical synchronization signal, thereby preventing power consumption due to unnecessary operation of the power supply unit in the power saving mode, thereby saving power. Can be obtained.

Claims (1)

Power saving of the monitor which controls the secondary output voltages V1, V2, V3 of the transformer T1 by controlling the power supply of the transformer T1 by detecting the voltage input from the power supply control IC 5 by receiving the power saving signal. In the power supply circuit, a horizontal synchronous signal detection unit 6 for detecting a horizontal synchronous signal HS, a vertical synchronous signal detection unit 7 for detecting a vertical synchronous signal VS, and the horizontal synchronous signal detection unit 6 or An optical coupler PC2 initially driven by the signal voltage detected by the vertical synchronous signal detector 7 and then driven by a voltage applied by the transistor Q1 to supply operating power to the power control IC 5; The microcomputer 8 which controls the transistor Q1 on / off by controlling whether the vertical sync signal HS or the horizontal sync signal VS is input by receiving the voltage V3 output from the transformer T1. And a voltage of 12V applied by switching on / off under the control of the microcomputer 8 And a buffer transistor (Q1) for supplying the optical coupler (PC2).