KR19990027231U - Monitor B + Voltage Generation Circuit - Google Patents

Abstract

The present invention relates to a B + voltage generating circuit of a monitor for generating a B + voltage applied to a primary winding of a flyback transformer 40 to generate an anode high voltage (HV) supplied to a monitor tube. A B + voltage generating circuit of a monitor adapted to compensate for the size of.

According to the present invention, as the user increases the contrast of the screen, when the anode high voltage (HV) decreases below the reference value and the size of the screen becomes large, the PWM controller 10 is outputted from the feedback (FB) terminal of the flyback transformer 40. The ABL voltage output from the ABL terminal of the flyback transformer 40 is inverted and amplified by the inverting amplifier 11 to add the feedback voltage to the feedback voltage, thereby stabilizing the anode high voltage (HV) and increasing the abnormally large screen size to the normal size. It is supposed to be corrected.

Description

Circuit for generating B + voltage in a monitor

The present invention relates to a B + voltage generating circuit of a monitor for generating a B + voltage applied to a primary winding of a flyback transformer (FBT) to generate an anode high voltage (HV) supplied to a monitor tube. A B + voltage generating circuit of a monitor adapted to compensate for the size of.

In general, the B + voltage generator circuit of the monitor is a part of the power circuit that serves to supply the voltages required by each part of the monitor, and in particular, a certain level output from the switching mode power supply (SMPS) of the monitor. A circuit for generating a B + voltage applied to the primary winding of the flyback transformer in order to generate an anode high voltage (HV) supplied to a water pipe by receiving a DC voltage of. In addition, the B + voltage generator circuit receives the feedback voltage from the feedback (FB) terminal of the flyback transformer and stabilizes the anode high voltage (HV) by adjusting the magnitude of the B + voltage, which is the video mode of the monitor. The magnitude of the voltage varies.

1 is a diagram illustrating a conventional B + voltage generation circuit, comprising: a PWM controller 20; A switching driver 30; It is composed of a switching unit 40, the action is as follows.

The PWM controller 20 receives a horizontal drive signal from a horizontal oscillator (not shown) and generates a PWM control signal synchronized with the horizontal drive signal. The switching driver 30 generates a switching device according to the PWM control signal. On / off, the switching unit 40 switches the DC input voltage DCin as the switching element of the switching driver 30 on / off and outputs a B + voltage to the primary winding of the flyback transformer. Allow it.

At this time, the anode high voltage (HV) is induced in the secondary winding of the flyback transformer by the B + voltage supplied to the cathode of the water pipe to the PWM controller 20 through the feedback (FB) terminal of the flyback transformer. The output characteristic is stabilized as the duty ratio of the PWM control signal output from the PWM controller 20 is changed by the magnitude of the feedback voltage fed back. That is, when the magnitude of the anode high voltage (HV) increases above the reference value, the feedback voltage increases together, and thus the PWM controller 20 outputs a PWM control signal having a small duty ratio to lower the B + voltage, thereby reducing the anode high voltage (HV). ), And the feedback voltage decreases when the size of the anode high voltage (HV) is lower than the reference value. Therefore, the PWM controller 20 outputs a PWM control signal having a large duty ratio to output the B +. By increasing the voltage, the size of the anode high voltage (HV) is increased to within a standard value.

However, even when the anode high voltage (HV) is stabilized by the B + generation circuit as described above, when the user increases the contrast of the screen in a specific video mode in which a deflection current is constant, the anode high voltage (HV) becomes the B + generation circuit. There is a problem that the size of the screen is abnormally large as it is reduced to a large extent that can not be adjusted by the acceleration and the electrons emitted from the cathode of the water tube cannot be accelerated normally.

Thus, in order to solve the above problems, the present invention adds the ABL voltage output from the ABL terminal of the flyback transformer to the feedback voltage output from the feedback (FB) terminal of the flyback transformer and fed back to the PWM controller. By stabilizing the anode high voltage (HV) is to provide a B + voltage generating circuit of the monitor to correct the size of the screen.

The present invention devised to achieve the above object, the PWM controller is synchronized to the horizontal drive signal, and generates a PWM control signal whose duty ratio is variable in accordance with the magnitude of the feedback voltage fed back from the flyback transformer, The switching driver turns on / off the switching element according to the PWM control signal, and the switching part switches the DC input voltage DCin to generate the B + voltage as the switching element of the switching driver is turned on / off. The anode high voltage is obtained by inverting and adding the ABL voltage output from the ABL terminal of the flyback transformer to the feedback voltage output from the feedback (FB) terminal of the flyback transformer and fed back to the PWM controller. And to stabilize (HV).

The device of the present invention configured as described above outputs from the feedback (FB) terminal of the flyback transformer when the anode high voltage (HV) decreases below a reference value and the size of the screen increases as the user increases the contrast of the screen. The ABL voltage output from the ABL terminal of the flyback transformer is inverted and added to the feedback voltage fed back to the PWM controller to stabilize the anode high voltage (HV) and to increase the abnormally large screen size to a normal size. It is supposed to be corrected.

1 is a view showing a conventional B + voltage generation circuit,

2 is a diagram illustrating a B + voltage generation circuit according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: PWM controller 11: inverting amplifier

20: switching driver 30: switching unit

40: Plaback Transformer

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

2 is a diagram illustrating a B + voltage generation circuit according to the present invention.

As shown in FIG. 2, an embodiment according to the present invention includes a PWM controller 10; Inverting amplifier 11; Switching drive unit 20; A switching unit 30; It comprises a flyback transformer 40, the operation of which is described as follows.

In the embodiment according to the present invention, the PWM controller 10 is synchronized to the horizontal drive signal, the duty ratio is variable in accordance with the magnitude of the feedback voltage fed back from the feedback (FB) terminal of the flyback transformer 40 Generates a PWM control signal, the switching driver 20 turns on / off the switching element according to the PWM control signal, and the switching unit 30 is turned on / off as the switching element of the switching driver 20 is turned on. The DC input voltage DCin is switched to generate the B + voltage. In addition, the inverting amplifier 11 inverts and amplifies the ABL voltage outputted from the ABL terminal of the flyback transformer 40 so that the brightness of the screen does not exceed a reference value (the feedback of the flyback transformer 40). FB) is added to the feedback voltage output from the terminal and fed back to the PWM controller (10).

If the user increases the contrast of the screen, the screen becomes bright and the anode high pressure (HV) applied from the secondary winding of the flyback transformer 40 to the cathode of the water pipe is reduced. As HV decreases, the screen size increases. In addition, the ABL terminal of the flyback transformer 40 outputs an ABL voltage having a low voltage value to prevent the brightness of the screen from exceeding a reference value or more.

In this case, when the anode high voltage HV decreases, a feedback voltage having a low voltage value is applied to the PWM controller 10 through the feedback FB terminal of the flyback transformer 40. Even when the PWM controller 10 outputs a PWM control signal having a large duty ratio, the anode voltage HV does not increase so as to reduce the size of the screen, which has been enlarged, to a normal size as the user increases the contrast. .

However, if the inverting amplifier 11 inverts the ABL voltage output from the flyback transformer 40 and adds it to the feedback voltage of the flyback transformer 40, the feedback voltage of the feedback voltage applied to the PWM controller 10 is increased. The value becomes even lower. Therefore, the duty ratio of the PWM control signal output from the PWM controller 10 becomes greater than before the inverted amplifier voltage output from the inverting amplifier 11 is added to the feedback voltage of the flyback transformer 40. As the user increases contrast, the anode high voltage HV is increased to reduce the size of the screen, which has been enlarged, to a normal size.

Here, as shown in FIG. 2, the amplification degree of the inverting amplifier 11 is determined by the ratio (-R2 / R1) of the voltage gain controlling resistor R1 and R2, and the feedback FB of the flyback transformer 40. The feedback voltage outputted from the terminal and rectified and smoothed is dropped by the resistor R4, and the output voltage of the inverting amplifier 11 is dropped by the resistor R3 and mixed with each other at the point A shown in FIG. To the controller 10.

As described above, according to the present invention, the anode high voltage is added by adding the ABL voltage output from the ABL terminal of the flyback transformer to the feedback voltage outputted from the feedback (FB) terminal of the flyback transformer and fed back to the PWM controller. When the screen size is corrected by stabilizing HV, the screen size can be kept constant even if the contrast of the screen changes.

Claims (1)

The PWM controller 10 is synchronized with the horizontal drive signal, generates a PWM control signal whose duty ratio is variable according to the magnitude of the feedback voltage fed back from the flyback transformer 40, and the switching driver 20 generates the PWM control signal. The switching element is turned on and off, and the switching unit 30 switches the DC input voltage DCin to generate the B + voltage as the switching element of the switching driver 20 is turned on / off. To ABL voltage output from the ABL terminal of the flyback transformer 40 to a feedback voltage output from the feedback (FB) terminal of the flyback transformer 40 and fed back to the PWM controller 10 is converted into an inverting amplifier 11. The B + voltage generating circuit of a monitor characterized by stabilizing the anode high voltage (HV) by inverting and amplifying by adding.