KR100228169B1 - High-voltage stabilizing circuit in multi-think monitor - Google Patents

Abstract

The present invention provides a high pressure stabilization circuit of a multi-sink monitor.

The high voltage stabilization circuit includes a primary coil having a first coil and a second coil to which a collector output of a horizontal output transistor is commonly applied to one side and a separate predetermined voltage is applied to the other side, and the primary coil. A flyback transformer comprising a secondary coil for converting a pulse voltage of the high voltage; A capacitor and a first diode having a parallel configuration connected between the applied power supply and the other side of the first coil to apply the predetermined voltage to the other side of the first coil from the applied power supply; A mode adjusting circuit which receives a multi-sink signal and outputs a driving signal in a high frequency mode; A horizontal drive transistor operated by a drive signal of the mode control circuit; The gate is connected to the collector of the horizontal drive transistor, the drain is connected to the applied power supply, and the source is connected to the other side of the second coil via a second diode to operate in the operation of the horizontal drive transistor in the high frequency mode. It characterized in that it comprises a field effect transistor.

Accordingly, even if any frequency of the high or low frequency is input, the high pressure output from the FBT always has a stable and stable value.

Description

High Voltage Stabilization Circuit for Multi-Sink Monitors

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high pressure stabilization circuit of a multi-sink monitor, and more particularly to a multi-sink monitor to which high and low horizontal deflection frequencies are applied.

In general, the sawtooth wave current of the horizontal deflection of the cathode ray tube is the largest in the return period after the end of the scan when the current change per unit time is large. Therefore, the output circuit generates a pulse voltage proportional to the change in current per unit time, and the magnitude thereof is equal to 8 of the DC power supply voltage for the output circuit. 10 times.

Therefore, this voltage is applied to the collector DC power supply of the horizontal output Tr than other transistor power supplies, and the pulse voltage generated during the return period is increased to further increase the pulse voltage from the boost flyback transformer (FBT) to a higher voltage. Boost up.

In addition, the output of the boost transformer is 10 Even if it is about 25 degrees, the anode voltage of cathode ray tube is 25 30 It is possible to boost the pressure.

The high voltage circuit is composed of a combination of a pulse generator circuit, a boost transformer, and a double voltage rectifier circuit in this manner. 30 Getting high pressure.

Such high voltage power supplies are stabilized in various ways, and in the case of a multi-sync monitor, it is necessary to stabilize the high voltage according to the mode of the horizontal deflection frequency. As an example, a stabilization circuit according to a conventional horizontal deflection frequency mode is shown in FIG.

In FIG. 1, the + B power supply is stabilized by separating the + B1 and + B2 to the flyback transistor FBT according to the frequency by the relay R to stabilize the high voltage. That is, as the mode control circuit 10 turns on / off the horizontal drive transistor Q3 in accordance with the mode, the relay R is excited / hatched, and the contacts Ra and Rb are selectively turned on / off and the above-mentioned + B The power supply is connected to either + B1 or + B2. Accordingly, the output from the horizontal output transistor Q2 is boosted differently in the flyback transistor FBT according to the frequency to stabilize the high pressure.

By using the relay R as described above, a noise problem occurs during chattering and mode switching, which are structural problems of the relay R. In addition, the chattering malfunctions the relay (R), which can seriously damage the reliability of the monitor, and the noise problem has a problem that users have a disgust when using the monitor. There is also.

Therefore, the present invention has been made in order to solve the above problems, the present invention is a simple configuration with a high pressure stabilization according to the frequency for stabilizing the high pressure of the multi-sink monitor that can operate accurately without noise, chattering The purpose is to provide a circuit.

1 is a circuit diagram showing the configuration of a high voltage stabilization circuit of a conventional multi-sink monitor.

2 is a circuit diagram showing the configuration of a high voltage stabilization circuit of a multi-sink monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: mode adjustment circuit Q1: field effect transistor (FET)

Q2: horizontal output transistor Q3: horizontal drive transistor

R: Relay

In order to achieve the above object, according to the present invention, the high-voltage stabilization circuit according to the high / low conversion of the horizontal deflection frequency of the multi-sink monitor has a collector output of a horizontal output transistor in common on one side and a separate output on the other side. A flyback transformer including a primary coil having a first coil and a second coil to which a predetermined predetermined voltage is applied, and a secondary coil for converting a pulse voltage of the primary coil into a high voltage; A capacitor and a first diode having a parallel configuration connected between the applied power supply and the other side of the first coil to apply the predetermined voltage to the other side of the first coil from the applied power supply; A mode adjusting circuit which receives a multi-sink signal and outputs a driving signal in a high frequency mode; A horizontal drive transistor operated by a drive signal of the mode control circuit; The gate is connected to the collector of the horizontal drive transistor, the drain is connected to the applied power supply, and the source is connected to the other side of the second coil via a second diode to operate in the operation of the horizontal drive transistor in the high frequency mode. It characterized in that it comprises a field effect transistor.

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

In the high-voltage stabilization circuit of the multi-sink monitor according to the present invention, the collector coil of the horizontal output transistor Q2 is commonly applied to one side of the primary coil of the flyback transformer FBT, and a predetermined voltage is separately separated to the other side. (+ B1, + B2) is composed of a first coil and a second coil to be applied, respectively.

On the other side of the first coil, the capacitor C1 and the first diode D1 are applied to the other side of the applied power source (+ B) and the first coil such that the predetermined voltage (+ B1) is applied from the applied power source (+ B). Is connected between.

An applied power supply (+ B) is connected to the second coil via a field effect transistor (FET), and the field effect transistor (FET) is driven by the horizontal drive transistor (Q3) so that the collector of the horizontal drive transistor (Q3). The gate is connected to the drain, the drain is connected to the applied power supply (+ B), the source is connected to the other side of the second coil via the second diode (D2).

The mode driving circuit 10 is connected to the horizontal driving transistor Q3 to receive a multi-sync signal and to output a driving signal in the high frequency mode.

The operation according to the configuration of the embodiment of the present invention described above is as follows.

In a multi-sink or multi-mode monitor having multiple horizontal deflection frequencies, if a mode signal is input to the mode adjusting circuit 10, + B is the mode adjusting circuit 10 when the mode adjusting circuit 10 is in the low frequency mode. A low signal is outputted, the horizontal driving transistor Q3 is turned off, and the gate of the field effect transistor FET is turned high, so that the field effect transistor FET is turned off, so that the applied power (+ B) is applied to the diode D1. Is applied to the + B1 part of the FBT. At this time, the + B power supply is charged to the capacitor C1 and acts as designed to be boosted in the FBT.

However, when the video signal is in the high frequency mode, the average current rises while the voltage falls, so it is necessary to compensate for this. Therefore, when the high frequency is input to the mode control circuit 10, the output goes high and the horizontal drive transistor Q3 is turned on. Accordingly, the gate of the field effect transistor (FET) is turned low, so that + B power is applied to the + B2 part in addition to the + B1 part of the FBT described above, and the voltage boosted on the secondary side of the FBT is compensated for the low frequency. Step up to the same voltage as.

According to the configuration and operation of the embodiment of the present invention described above, even if any frequency of the high or low frequency is input, the high pressure output from the FBT has the effect of always maintaining a stable constant value.

Although one embodiment of the present invention has been described above, the present invention is not limited thereto, and those skilled in the art will be able to apply and modify the same in various ways.

Claims (1)

In the high voltage stabilization circuit according to the high / low conversion of the horizontal deflection frequency of the multi-sink monitor, the collector output of the horizontal output transistor Q2 is applied to one side in common, and a predetermined separate voltage (+ B1, A flyback transformer (FBT) including a primary coil having a first coil and a second coil to which + B2) is applied, and a secondary coil for converting a pulse voltage of the primary coil into a high voltage; A capacitor C1 and a first diode D1 having a parallel configuration connected between the applied power supply (+ B) and the other side of the first coil at the other side of the first coil; A mode adjusting circuit 10 which receives a multi-sink signal and outputs a driving signal when it is in a high frequency mode; A horizontal drive transistor Q3 operated by a drive signal of the mode control circuit 10; The gate is connected to the collector of the horizontal driving transistor Q3, the drain is connected to the applied power supply (+ B), and the source is connected to the other side of the second coil via the second diode D2, so that the high frequency mode is connected. And a field effect transistor (FET) which is operated by the operation of the horizontal drive transistor (Q3) when the high voltage stabilization circuit of the multi-sink monitor.