KR200239038Y1 - High voltage rise prevention circuit - Google Patents

Abstract

The present invention relates to a high pressure increase prevention circuit for preventing a high pressure that is raised when damage to the components of the feedback stage for feeding back a high pressure, in a circuit for maintaining a constant high pressure applied to the anode of the CRT, A voltage output terminal for outputting a voltage for driving the CRT, a high voltage feedback terminal for detecting and feeding back the voltage induced by the voltage output terminal, and a voltage lower than a normal control voltage when the output voltage of the high voltage feedback terminal is lower than or equal to a predetermined voltage; A voltage control stage for outputting a high voltage duty stage for controlling a pulse width duty ratio to output a low voltage when a voltage lower than a normal control voltage is output from the voltage control stage; A voltage output stage that is driven by the output of the To a high voltage generation stage, including that the output pressure.

Description

High voltage rise prevention circuit

The present invention relates to a high-voltage circuit applied to the CRT of the monitor, and more particularly to a high-voltage rise prevention circuit for preventing the high pressure that is raised when the components of the high-pressure feedback stage for feeding back the high pressure (feed back).

Generally, a monitor, which is a representative peripheral device of a computer (hereinafter, referred to as a PC), is a device that receives a video signal output from a PC and displays it through a cathode ray (CRT).

That is, a rectifying stage (not shown) receives a horizontal synchronizing signal H-SYNC and a vertical synchronizing signal V-SYNC for synchronizing the image signals R, G, and B output from a PC video card. Various driving voltages required in the CRT by receiving the direct current rectified through the output, that is, the high voltage required by the anode of the CRT, and an appropriate voltage to the connection electrode in the CRT to connect the electron beam of the CRT on the fluorescent surface The monitor receives an input of a focus voltage and an R, G, and B signals applied from a video card of a computer, and displays an image on a monitor, and displays an image signal by receiving a screen voltage.

Looking at the process of generating the high pressure in more detail with reference to Figure 1, by receiving the high-pressure output from the secondary transformer (T2) of the voltage output terminal (1) through the high-pressure feedback terminal (2) 3).

At this time, when the voltage applied to the high pressure duty generating stage 3 is low, the high pressure duty generating stage 3 increases the on time (high level) of the PWM (pulse modulation width) duty to the high pressure generating stage 4. By outputting, the output voltage of the high voltage generator stage 4 is increased. On the contrary, when the voltage applied to the high pressure duty generator stage 3 is high, the duty on time of the PWM pulse is reduced to reduce the voltage of the high voltage generator stage 4. Lower it.

However, if the components themselves constituted in the high-pressure feedback terminal 2 that feeds back the high pressure are damaged, the high-voltage duty occurs because the feedback voltage is not input to the high-pressure duty generating stage 3 even though the set of the apparatus is operating normally. The stage 3 recognizes this as an error (low voltage), controls the duty width, and adjusts the high pressure generator 4 so that the voltage output from the high voltage generator 4 is increased.

Therefore, the output voltage of the high voltage generating stage 4 rises high, thereby causing damage to the set or damaging parts.

Where Q1 is a horizontal output transistor, D1 represents a damper diode, L _Y represents a horizontal deflection yoke, and C _S represents a capacitor for S correction.

The present invention has been made to solve the above problems, an object of the present invention is to provide a high pressure increase prevention circuit for preventing the high pressure is raised when the parts of the high-pressure feedback stage that feeds back the high pressure.

The present invention for achieving the above object is a circuit for maintaining a constant high voltage applied to the anode of the CRT, the voltage output stage for outputting the voltage for driving the CRT, and the voltage induced in the voltage output terminal A high-voltage feedback terminal for feeding back the voltage, a voltage control terminal for outputting a voltage lower than a normal control voltage when the output voltage of the high-voltage feedback terminal is below a predetermined voltage, and a high voltage is generated when a voltage lower than the normal control voltage is input from the voltage control terminal. Outputs a predetermined voltage to a high voltage duty stage for controlling the pulse width duty ratio to output a low voltage and a voltage output stage driven by the output of the high voltage duty stage to provide a supply power for driving the CRT. It is characterized by including the high-pressure generator

Figure 1 shows a conventional general high pressure rise prevention circuit,

2 relates to a high pressure rise prevention circuit according to the present invention.

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the subject innovation in detail as follows.

2 is a high-voltage rise prevention circuit according to the present invention.

As shown, the present invention detects the amount of high voltage induced in the secondary transformer T2 of the voltage output terminal 10 that outputs a high voltage and a focus voltage and a screen voltage. When the high voltage is grounded or falls below a certain voltage due to a component of the high pressure feedback terminal 20 for feeding back the control unit, it is controlled before being applied to the high pressure duty generating stage 40, thereby controlling a constant voltage. It is also a structure in which a voltage control stage 30 for application is added.

In detail, the CRT (not shown) is a video signal output from a PC (not shown) by receiving a high voltage, a focus voltage and a screen voltage output from the primary transformer T1 of the voltage output terminal 10. Display (R, G, B).

Among these voltages, in order to apply a high voltage that requires more than 23 KV in particular, the diode D2 configured in the high voltage feedback terminal 20 by detecting a voltage induced in the secondary transformer T2 of the voltage output terminal 10. And rectified and smoothed by the capacitor C1, and then distributed by the resistors R1 and R2 and fed back to the high-voltage duty generating stage 40 via the current limiting resistor R3 of the voltage control stage 30.

As such, if the voltage applied to the high-pressure duty generating stage 40 is a normal voltage, the high-pressure duty generating stage 40 controls the high-pressure generating stage 50 so that normal high pressure is applied to the anode of the CRT, so that an image is generated. Is displayed.

At this time, when the high pressure output from the primary transformer T1 of the voltage output terminal 10 is changed and detected by the secondary transformer, the voltage passing through the high pressure feedback terminal 20 is also slightly changed and the high pressure duty generating stage 40 is performed. ) Recognizes this and controls the high pressure generating stage 50 so that the high pressure can be kept constant by controlling the duty of the output PWM pulse.

If, the rectifying diode (D2) and the capacitor (C1) or the voltage divider resistor configured in the high-voltage feedback terminal 20 for detecting and feeding back the voltage induced in the secondary transformer (T2) of the voltage output terminal 10 ( When parts such as R1 and R2 are damaged, the output voltage passing through the high-voltage feedback terminal 20 falls below a certain voltage or is grounded.

That is, when the voltage passing through the high-voltage feedback terminal 20 is grounded above the component or falls below a certain voltage, that is, V _CC falls below 0.7V, the transistor Q2 of the voltage control stage 30 becomes conductive. Therefore, the V _CC voltage is applied to the high pressure duty generating stage 40 via the lower limit R5.

At this time, the voltage input to the V _CC of the voltage control terminal 30 is applied a voltage slightly lower than the normal feedback voltage, so that the high-voltage duty generating stage 40 is a feedback voltage passed through the high-voltage feedback terminal 20 By recognizing the high pressure generating stage 50 is controlled.

Therefore, the high voltage generating stage 50 applies a high pressure slightly lower than normal to the voltage output 10, thereby applying a high pressure output through the voltage output terminal 10 or a high pressure lower than the normal high pressure to the CRT.

That is, when the state displayed through the CRT suddenly increases in the H-size, the V-Size decreases or the brightness of the screen changes, the user becomes an abnormal set. It is determined that this has occurred and the device is checked.

As described above, the voltage input to the high-pressure duty generating stage is always kept constant, thereby minimizing the damage of the set, thereby obtaining a stable high voltage.

Claims (2)

In the circuit for maintaining a constant high voltage applied to the anode of the CRT, A voltage output stage for outputting the voltage for driving the CRT, a high voltage feedback stage for detecting and feeding back the voltage induced by the voltage output terminal, and a normal control voltage complement is low when the output voltage of the high voltage feedback stage is less than a predetermined voltage. A zone voltage control stage for outputting a voltage, a high voltage duty generation stage for controlling and outputting a duty ratio of a pulse width so that the high voltage generator outputs a low voltage when a voltage lower than the control voltage is received from the voltage control stage; And a high voltage generating stage which outputs a predetermined voltage to a voltage output stage which is driven by an output of the stage and provides a supply power for driving the CRT. The voltage output stage may include a primary transformer T1 for outputting a high voltage, a focus voltage, and a screen voltage. And a secondary transformer (T2) for detecting a voltage induced by the primary transformer (T1).