KR0138557Y1 - Screen voltage stabilizing circuit - Google Patents

Abstract

The present invention relates to a screen voltage stabilization circuit that can be reproduced on a television in the state of the transmission signal by allowing the screen voltage to be constantly applied to the CRT (Cathode Ray Tube) irrespective of the brightness of the screen so that black level change does not occur. This is to solve the problem that the screen voltage is changed according to the brightness of the screen, i.e., the reception of the dark screen and the reception of the bright screen.

To this end, the present invention provides a flyback transformer having a horizontal output transistor and a video voltage line connected to the primary side.

It is provided with a rectifier for converting the pulse output of the horizontal output transistor into a rectified flat to convert to a DC voltage, and an adjustment element for applying the DC voltage to the screen voltage by setting the variable range and voltage level.

Description

Screen voltage stabilization circuit

1 is a conventional circuit diagram.

(A) of FIG. 2 is an IF waveform diagram.

(b) is a CRT cathode waveform diagram.

(c) is the slope of the voltage according to the change of IRE.

3 is a circuit diagram of the present invention.

4 is a graph of screen voltage comparison between the present invention and the prior art.

* Explanation of symbols for main parts of the drawings

Q1: Horizontal output transistor FBT: Flyback transformer

C1, C2, C3: Capacitor D1, D2: Diode

The present invention relates to a video reproducing apparatus for receiving and reproducing a broadcast signal transmitted from a broadcasting station in a transmission signal state. In particular, a black level change occurs because a screen voltage is constantly applied to a CRT (Cathode Ray Tube) regardless of screen brightness. The present invention relates to a screen voltage stabilization circuit that can be reproduced on a television in a state of a transmission signal by preventing the loss of a signal.

In televisions, there is a problem in that the screen voltage is fluctuated according to the brightness of the screen, that is, the reception of the dark screen and the reception of the bright screen.

This phenomenon occurs because the focus voltage and the screen voltage are drawn out from the secondary high voltage terminal of the flyback trans built in the television.

That is, as shown in FIG. 1, the horizontal output transistor Q1 and the deflection coil DY are connected to the primary side of the flyback transformer FBT, and at the secondary high voltage terminal of the flyback transformer FBT. The focus voltage and the screen voltage are drawn out.

In this way, the screen voltage is drawn from the middle terminal of the high voltage (25KV) applied to the CRT inside the flyback transformer (FBT). Therefore, if the brightness control or contrast control function of the television is changed, the CRT high voltage is changed. This fluctuation of the CRT high pressure was also displayed on the screen voltage as it is, and was reproduced distorted instead of being reproduced in the state of the transmission signal.

That is, when the IF waveform as shown in FIG. 2A is received, the video voltage 180V is applied to the primary side of the flyback transformer FBT to apply the waveform shown in FIG. 2B at the cathode of the CRT.

At this time, the screen voltage is drawn out from the secondary side of the flyback transformer (FBT), and the video voltage changes in the DC voltage value when the contrast component of the white pattern is 0%, 10% ................... 100%, respectively. Although the screen voltage is 50% of the Institute of Radio Engineering (IRE) at IF waveform (point A in Fig. 2 (c)), the screen voltage is 0% if the screen voltage is fixed so that the black level is not emitted to the CRT. When is input, the screen voltage becomes high (site B in Fig. 2 (c)), and the black level shines brightly and the 100% IRE signal is input (site C in Fig. 2 (c)), forcibly increasing the screen volume. As a result of lowering the screen voltage, dark areas close to the black level are identified with black, and thus the CRT does not emit light, and thus a difference occurs with real eyes like the black level.

In other words, when transmitting a dark screen with low contrast gain at the transmitting station, the screen voltage increases as the high voltage is increased during playback on the CRT, and the black level of the screen is brightly emitted, and the dark part where the contrast gain is large and there is not much difference with the black level appears at the transmitting station. When the screen is transmitted, the screen voltage is lowered as the high pressure is lowered during playback, so that the dark level near the black level is not reproduced.

The present invention has been devised in view of the above, and the DC level change which reduces the voltage fluctuation applied to the screen terminal of the CRT and distorts the signal sent from the transmitting station when the signal appearing at the cathode of the CRT is applied to the CRT screen. By minimizing the power consumption, the present invention can reproduce the same signal as the transmission signal, and the present invention does not draw the TV screen voltage in the middle of the high voltage of the secondary side of the flyback transformer. Is rectified to configure voltage to the screen terminal of the CRT.

Hereinafter, the present invention will be described in detail with reference to the circuit diagram of FIG. 3.

In a circuit in which the horizontal output transistor Q1 and the video voltage line are connected to the primary side of the flyback transformer FBT,

And a screen voltage generating means for rectifying the voltage of the selector pulse of the horizontal output transistor Q1 and applying the voltage to the screen voltage.

The screen voltage generating means includes a rectifier for rectifying the collector pulse of the horizontal output transistor Q1, and an adjusting element for adjusting the variable range and voltage of the voltage rectified by the rectifier.

That is, by adjusting the collector pulse of the horizontal output transistor Q1 to the resistor R1, the rectifier is configured to rectify and smooth the diode D1 and the capacitor C3.

The regulating element is configured to adjust the variable range of the voltage rectified by the rectifier with the resistors R2-R4, while setting the voltage level with the variable resistor VR1 to apply the screen voltage.

In addition, a screen voltage ripple removing capacitor C1 is connected between the video voltage line and the screen voltage line.

The present invention configured as described above has a change in the high voltage, which is the anode applied voltage of the CRT according to the brightness of the screen, and accordingly the screen voltage is proportionally interlocked so that the black level does not change depending on the brightness of the waveform applied to the cathode of the CRT. Regardless of the transmission signal, the black level emits light when the screen is dark and the signal component higher than the black level does not emit light when the screen is the same as the black level.

In other words, the present invention adjusts the collector pulse of the horizontal output transistor Q1 connected to the primary side of the flyback transformer FBT with a resistor R1 regardless of the beam change (IRE change) to the diode D1 and the capacitor. DC rectification is made by rectifying and smoothing with (C3).

The DC voltage converted by the diode D1 and the condenser C3 is set to the screen voltage variable range by the resistors R2-R4, and then adjusts the variable resistor VR1 to set and output the screen voltage.

This ensures that the screen voltage does not change the screen voltage regardless of the input signal change (IRE change) so that the black level signal is visible even when a dark screen (low IRE screen) and bright screen (high IRE screen) are received. It is possible to reproduce the contrast characteristics of the screen according to the transmission signal by not letting the CRT emit only the signals below the black level.

On the other hand, the ripple cancellation capacitor (C1) of the screen voltage is connected to the video voltage line without being connected to ground, so that the same effect occurs when an impulse noise splashes on the video voltage line or the screen voltage line from the outside or the CRT itself. By doing so, it was possible to compensate.

The screen voltage variation of the present invention is only 20V, as shown in FIG. 4, but the existing circuit is about 70V. Therefore, the present invention stabilizes the screen voltage as the screen voltage variation is low, so that the brightness of the screen is close to the transmission signal. Can be reproduced.

Claims (2)

In the screen voltage stabilization circuit in which the horizontal output transistor Q1 and the video voltage line are connected to the primary side of the flyback transformer FBT, the collector pulse output of the horizontal output transistor Q1 connected to the primary side of the flyback transformer FBT is connected. A rectifier comprising a diode (D1) and a capacitor (C3) for rectifying smoothing and converting into a DC voltage, the variable range of the DC voltage changed in the rectifier is adjusted by the resistors R2-R4, and the voltage level is adjusted by the variable resistor VR1. And a regulating element for setting the voltage to the screen voltage. The screen voltage stabilization circuit according to claim 1, wherein an impulse removing capacitor (C1) is connected between the video voltage line and the screen voltage line connected to the primary side of the flyback transformer (FBT).