KR0135196B1 - A stabilizing circuit of horizontal size of monitor - Google Patents

Abstract

The present invention relates to a horizontal size stabilization circuit of a monitor that can always obtain a stable screen by compensating B ⁺ change according to a frequency change according to brightness, and a power supply unit for supplying a DC power supply, and a DC power supply from the power supply unit. And a chopper IC that converts AC into AC, and converts AC power of the chopper transformer back into DC to output B ⁺ power and receives a feedback voltage from a flyback transformer to maintain a constant B ⁺ voltage. A horizontal size stabilization circuit of a monitor, comprising: a brightness information amplifier for detecting a voltage in the FBT that varies according to screen brightness and amplifying it to a predetermined level; and a current flow in accordance with brightness information amplified by the brightness information amplifier. controlling hayeoseo and further comprising a voltage compensation circuit which compensates the voltage ⁺ B Jean would lure.

Description

Horizontal size stabilization circuit of the monitor

1 is a view showing a configuration for stabilizing the horizontal size of a conventional monitor

2 is a diagram showing the configuration of a horizontal size stabilization circuit of a monitor according to the present invention.

3 is a circuit diagram showing an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawing

10: power supply 20: chopper transformer

30: chopper IC40: brightness information amplifier

41: inverting amplifier 42: current controller

50: voltage compensation circuit section OP1: op amp

Q10: Transistor R11-R18: Resistance

C11-C13: Capacitor D10: Diode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a monitor, and more particularly, to a horizontal size stabilization circuit of a monitor capable of always obtaining a stable screen by compensating for a change in B ⁺ according to a frequency change according to brightness.

In general, when the monitor is used, the user can change the screen color as needed. For example, the screen color may be based on black and type white letters, or the screen color may be based on white and type black letters.

At this time, if the screen background color is white, the amount of (-) charges of each electron gun increases, so the anode voltage is lowered and the deflection of electrons is easier, so that the screen is spread widely. It is not smooth, and the screen is narrower than when it is white.

This is when the deflection distance h, the magnetic field strength B, the distance from the electron gun to the screen L, the deflection coil distance l, and the anode voltage of the water pipe are Ea.

This can be explained by the principle.

The high voltage generation circuit diagram of the conventional monitor includes a power supply unit 10 for supplying DC power as shown in FIG. 1, a chopper transformer 20 for converting DC power from the power supply unit 10 into AC, and The AC power of the chopper transformer 20 is converted to DC again and B⁺Outputs power and receives feedback voltage from flyback transformer B⁺A chopper IC 30 composed of a transistor Q1-Q3, a resistor R2-R5, a zener diode ZD1, and a capacitor C1 for maintaining a constant voltage, the power supply unit 10 and a chopper prince ( And a resistor R1 connected between the common contact of 20) and the base of the transistor Q1. Here, the chopper transformer 20 and the chopper IC 30 constitute one chopper.

In the circuit of the conventional monitor configured as described above, when a direct current (about 164 V) power is supplied through the power supply unit 10, the chopper transformer 20 is converted into alternating current, and the transistor of the chopper IC 30 is passed through the resistor R1. By turning on (Q1), the horizontal output circuit could be driven by converting an alternating current through the chopper transformer 20 into a B ⁺ voltage and outputting it to the flyback transformer.

In addition, the voltage from the flyback transformer is fed back and applied to the base of the transistor Q3 to turn on the transistor Q3 so that the base voltage of the transistor Q2 is varied, resulting in a B ⁺ voltage that is an output voltage of the transistor Q1. Could be kept constant.

However, in the horizontal size stabilization circuit of the conventional monitor as described above, the feedback for the mode is made of a variable voltage, but the feedback on the brightness is not made, so there is no compensation for screen brightness (amount of light).

In other words, the screen size fluctuates when the screen is displayed in the same mode as when it is displayed dark and when it is displayed brightly.

An object of the present invention is to provide a horizontal size stabilization circuit of a monitor that can achieve a stable screen by compensating for B ⁺ change according to a frequency change according to brightness.

In order to achieve the above object, the present invention provides a power supply unit for supplying a direct current power source, a chopper transformer for converting a direct current power supply from the power supply unit into an alternating current, and converts the alternating current power of the chopper transformer into direct current to generate a B ⁺ power A horizontal size stabilization circuit of a monitor comprising a chopper IC that receives a feedback voltage from a flyback transformer and maintains a constant B ⁺ voltage. The anode voltage in the FBT is detected by changing the brightness of the screen. It further comprises a brightness information amplifier for amplifying at a predetermined level and a voltage compensation circuit for controlling the current flow in accordance with the brightness information amplified by the brightness information amplifying unit to compensate for the B ⁺ voltage of the chopper. It is done.

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

2 is a block diagram of a horizontal size stabilization circuit of a monitor according to the present invention, a power supply unit 10 for supplying DC power, a chopper transformer 20 for converting DC power from the power supply unit 10 into AC, Transistors (C1-Q3) and resistors (R2-) that convert the AC power of the chopper transformer (20) back into direct current to output B ⁺ power and receive the feedback voltage from the flyback transformer to maintain the B ⁺ voltage constant. R5), a chopper IC (30) composed of a zener diode (ZD1) and a capacitor (C1), a resistor connected between the common contact of the power supply unit (10) and the chopper transformer (20) and the base of the transistor (Q1). A horizontal size stabilization circuit of a monitor configured to include R1), comprising: a brightness information amplifier 40 and a brightness information amplifier 40 for detecting a voltage in the FBT that varies according to screen brightness and amplifying it to a predetermined level; Amplified by bright According to the information configured to further comprise a voltage compensation circuit 50 to compensate the B ⁺ voltage to control the flow of current.

3 is a circuit diagram illustrating an embodiment of the brightness information amplifier 40 and the voltage compensation circuit unit 50. First, the brightness information amplifier 40 includes the op amps OP1, resistors R11-R13, and capacitors. An inverting amplifier 41 configured to invert and amplify a signal input through the EHT (Electric High Voltage Terminal) detection terminal of the FBT, a diode D10, a transistor Q10, and a resistor R14 (R15). And a condenser C10 and a current controller 42 for controlling the flow of current in the voltage compensating circuit unit 50 according to the signal amplified by the inverting amplifier 41.

The voltage compensating circuit unit 50 is composed of resistors R16-R18 and capacitors C12 and C13 to feed back the brightness information amplified by the brightness information amplifying unit 40 to the output terminal of the chopper for the B ⁺ voltage. It is configured to compensate.

According to the present invention configured as described above, when the screen is bright, a low level signal is input through the EHT detection terminal of the FBT. On the contrary, when the screen is dark, a high level signal is input through the EHT detection terminal of the FBT.

Therefore, when the screen becomes bright, the low level signal is input through the op amp OP1, inverted, amplified to a predetermined level, and input to the base of the transistor Q10 of the current controller 42.

In this way, the current flowing from the collector of the transistor Q10 to the emitter side through the resistor R18 of the voltage compensating circuit unit 50 increases according to the signal input to the base of the transistor Q10, and thus flows relatively to the resistor R17 side. The current will be less, resulting in a smaller B ⁺ voltage, which will reduce the size of the screen.

On the contrary, when the screen is dark, the high level signal is input to the op amp OP1 through the EHT detection terminal of the FBT, inverted and amplified through the output terminal of the op amp OP1, and then the transistor of the current control unit 42 It is input to the base of Q10).

Therefore, a small amount of current flows to the collector side of the transistor Q10 through the resistor R18 of the voltage compensating circuit unit 50, so that the current flowing through the resistor R17 increases.

As the current flowing through the resistor R17 increases, the size of the screen increases because the B ⁺ voltage increases. Here, the resistor R16 (R17) is a line through which B ⁺ flows directly, so that a large current element of 2W or more is obtained. Model resistors should be used.

The invention as described above automatically when quality by controlling the flow of current from the chopper compensated by the brighter the screen by giving the B ⁺ voltage increases the B ⁺ voltage as a function of frequency change according to eases dark, and when the screen is opened, By compensating the change of B ⁺ voltage according to the brightness more precisely, a stable screen can be obtained.

Claims (3)

A power supply for supplying DC power, a chopper transformer for converting the DC power from the power supply to AC, and converting the AC power of the chopper transformer to DC again to output B ⁺ power and supplying a feedback voltage from the flyback transformer In the horizontal size stabilization circuit of the monitor comprising a chopper IC that receives the input and maintains a constant B ⁺ voltage, A brightness information amplifying unit which senses a voltage in the FBT that varies according to screen brightness and amplifies it to a predetermined level; And a voltage compensation circuit unit configured to compensate for the B ⁺ voltage by controlling the flow of current according to the brightness information amplified by the brightness information amplifying unit. The apparatus of claim 1, wherein the brightness information amplifier unit inverts and amplifies a signal input through a terminal of the FBT; And a current controller for controlling the flow of current in the voltage compensation circuit according to the signal inverted and amplified by the inverting amplifier. The horizontal size stabilization circuit of a monitor according to claim 2, wherein the inverting amplifying unit includes an inverting amplifying op amp to which a voltage of FBT is applied as an inverting terminal.