KR960012842B1 - Circuit for electric power control at the off-mode state - Google Patents

Abstract

a switching means(10) switched by a level outputted from a control part if a vertical and a horizontal synchronization signal are not inputted; a photo coupler(20) feedbacking a current according to the switching of the switching means, being connected to the output terminal of the switching means; and a control means controlling the second side voltage of a switching transformer by controlling the basic switching frequency of the first side of the switching transformer according to the feedback current.

Description

Power control circuit in monitor off mode

1 is a power control circuit diagram in the off mode of the present invention.

* Explanation of symbols for main parts of the drawings

10 switching means 20 photo coupler

30: SMPS integrated circuit Q ₁ , Q ₂ : transistor

D _{1 to} D ₅ : diode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitor, and in particular, power control in the off mode of a monitor to achieve power saving by maintaining the power at 5 W or less in the off mode in the display power management signaling (DPMS) of the monitor. It is about a circuit.

In general, when the monitor is operating in normal mode, power consumption (approx. 80W) is achieved because the horizontal and vertical synchronization signals are in the mode active mode.However, if the monitor is not used for a certain period of time, As a means to prevent this, the power consumption circuit (DPMS) has recently been used to reduce power consumption.

In the power saving circuit, there are three modes, and according to each mode, power consumption can be reduced. There are a standby mode, a suspend mode, and an off mode.

First, in the standby mode, since the horizontal synchronous signal is in an inactive state and the vertical synchronous signal is in an active state, the degree of power consumption can be reduced to MiniMum.

In the suspend mode, since the horizontal synchronization signal is active and the vertical synchronization signal is inactive, the degree to which power consumption can be reduced becomes a signature.

That is, in the suspend mode, the power supply is stopped to the deflection circuit and the heater, and power is supplied only to the microcomputer, which is a control unit, to prevent unnecessary waste of power.

On the other hand, in the off mode, the horizontal synchronization signal is inactive and the vertical synchronization signal is inactive, so that the degree of power consumption can be reduced to the maximum.

The power consumed in the standby mode or the suspend mode is about 15W, so that the power consumed in the off mode when the monitor is normally used is 5W or less.

The present invention provides a power control circuit in the off mode of the monitor to reduce the power when not in use by controlling the power to 5W or less in the off mode in order to meet such a point. There is a purpose.

The present invention for achieving the above object is a circuit for adjusting the secondary voltage of the switching transformer through the error amplifier (Error Amp) in the normal mode, the output from the controller if the vertical, horizontal synchronization signal is not input in the off mode A switching means turned on by a predetermined level, a photocoupler for feeding back a large amount of current when the switching means is turned on, i.e., in an off mode, and the amount of current fed back by the photocoupler And controlling means for adjusting the basic switching frequency to bring down the secondary voltage of the switching transformer.

Hereinafter, an embodiment of a power control circuit in the off mode of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of the present invention, in which the first and second transistors are turned off in a normal mode and turned on by a predetermined level output from a controller (for example, a microcomputer) when no vertical or horizontal synchronization signal is input in an off mode. (Q ₁ ) (Q ₂ ), the switching means (10) consisting of a resistor (R ₁ ) (R ₂ ), a diode (D ₅ ) and when the switching means 10 is switched to drive back current In the normal mode, a small amount of current is fed back, and a large amount of current is fed back in the off mode. A photo coupler 20 including a photodiode and a photo transistor is provided, and the amount of current fed back by the photo coupler 20. As a result, the switching transformer T includes a switching mode power supply (SMPS) integrated circuit (1C) 30 which is a control unit for reducing the primary side frequency of the switching transformer T to lower the secondary side voltage.

In the drawings, reference numerals D _{1 to} D ₄ are diodes, R ₃ and R ₄ are resistors, 40 is an error amplifier, 50 is a constant voltage circuit, and 60 is a control unit such as a microcomputer.

According to the present invention configured as described above, when more than 165V is supplied through the secondary side diode D ₁ of the switching transformer T, for example, in the normal mode, the error amplifier 4 receives more current than the current at 164V. 20, a large amount of current is fed back to the SMPS integrated circuit 30 through the photo coupler 20. In the SMPS integrated circuit 30, the secondary side voltage of the switching transformer T is lowered to always maintain a constant voltage (here 165V) is applied to the load.

On the other hand, when the user uses the monitor but does not use the monitor for a certain period of time, that is, when no key signal is input from the keyboard, the display is in DPMS mode, a standby mode or a suspend mode to prevent power consumption of the monitor. Or the off mode.

For example, when the vertical and horizontal synchronizing signals are not input and enter the off mode, the control unit 60 such as a microcomputer detects this and sets a predetermined level (here, a high level) to the first transistor Q ₁ of the switching means 10. Output to the base.

Accordingly, as the first transistor Q ₁ is turned on, the second transistor Q ₂ is also turned on, and +165 V passes through the photo diode of the photo coupler 20 through the collector of the second transistor Q ₂ . The photodiode is turned on because it is applied to 40.

Accordingly, since the photo transistor is turned on to feed back a large amount of current to the SMPS integrated circuit 30, in the SMPS integrated circuit 30, when the primary side frequency of the switching transformer T is turned off at a normal 40 to 80 KHZ, Control to reduce to 15-20KHZ.

That is, in the off mode, a large amount of current is fed back to the SMPS integrated circuit 30 through the photo coupler 20, and thus the AC power input from the SMPS integrated circuit 30 and the current of the photo coupler 20. After receiving the input to the secondary side of the switching transformer (T) will be controlled to lower the voltage by increasing the current.

In other words, the SMPS integrated circuit 30 adjusts the primary side basic switching frequency of the switching transformer T, for example, by adjusting the primary side basic switching frequency of the switching transformer T, for example, the switching transformer T. On the secondary side of), 165V in normal mode is down to 70V, 80V is down to 35V, and 24V is down to about 10V, which disables horizontal deflection and vertical deflection, which reduces power consumption to 5W or less when off. It can be.

In the standby mode, + 5V supplied to the microcomputer, the control unit 60, is supplied at 24V. When the user enters the normal mode using the monitor again in the off mode, the horizontal sync signal and the vertical sync signal are input. After sensing and outputting a predetermined level (here, low level) to the base of the first transistor Q ₁ of the switching means 10, the first transistor Q ₁ is turned off and the second transistor Q ₂ is also turned off. .

Therefore, in the normal mode, the normal voltage is applied to the load side according to the operation of the error amplifier 40 regardless of the operation of the switching means 10.

As described above, the secondary voltage of the switching transformer T may always be constantly adjusted through the error amplifier 40 in the normal state, and the photo may be switched through the switching means 10 in the off mode. By allowing a large amount of current to be fed back from the coupler 20 to the SMPS integrated device 30, the secondary side of the switching transformer T has the effect of reducing the voltage to 5W or less in the off mode. .

Claims (4)

A circuit of a monitor for adjusting a secondary voltage of a switching transformer through an error amplifier in a normal mode, comprising: switching means switched by a predetermined level output from a control unit when a vertical or horizontal synchronization signal is not input in an off mode; A photo coupler connected to the output side of the switching means for feeding back current according to the switching of the switching means, and adjusting the primary side basic switching frequency of the switching transformer according to the amount of current fed back by the photo coupler to adjust the secondary side voltage of the switching transformer. Power control circuit in the off mode of the monitor, characterized in that it comprises a control means by adjusting the. The switching device of claim 1, wherein the switching means is connected to an output side of the control unit, the first transistor being turned on by a predetermined level in an off mode, and the base is connected to the collector of the first transistor to be turned on at the same time when the first transistor is turned on. And a second transistor, wherein the power control circuit is in the off mode of the monitor. 2. The power control circuit in an off mode of a monitor according to claim 1, wherein the anode of the photodiode of the photocoupler is connected to the collector of the second transistor and the cathode is connected to an error amplifier. 2. The monitor of claim 1, wherein the control means is an SMPS integrated circuit configured to receive a current fed back from the photocoupler and an alternating current input power to convert the primary side frequency of the switching transformer. Power control circuit.