KR20010111934A - Supply circuit of horizontal pulse signal - Google Patents

Abstract

Instead of using a separate synchronous signal voltage drop transformer, a horizontal pulse signal of a low voltage level is generated from the synchronous signal generating transformer of the horizontal output circuit and supplied to the SMPS circuit.

A power supply unit for converting an AC power source to a DC power source, a switching transistor switched according to a PWM signal, a switching transformer for guiding output power of the power source unit from a primary coil to a plurality of secondary coils according to the switching of the switching transistor, and a plurality of the switching transformers A plurality of rectifiers for converting a power source induced by a secondary coil into a DC power source and supplying operating power to a load, a horizontal output circuit generating a horizontal deflection signal according to a horizontal pulse signal, and detecting a horizontal pulse signal from the horizontal output circuit A monitor comprising a synchronous signal detecting transformer for operating a high voltage generating circuit and inputting the same to the PWM control unit, wherein the synchronous signal detecting transformer induces a horizontal pulse signal having a voltage level required by the PWM control unit. It is provided with a tertiary coil integrally, and the horizontal guided by the tertiary coil The pulse signal is input directly to the PWM controller.

Description

Supply circuit of horizontal pulse signal

According to the present invention, in a monitor using a cathode ray tube as an image display means, a horizontal pulse signal of low voltage is used in a switching mode power supply (SMPS) circuit for supplying operating power, without using a separate synchronous signal voltage drop transformer. It relates to a horizontal pulse signal supply circuit for supplying a.

In general, a monitor using a cathode ray tube as a display element has a high pressure for accelerating an electron beam output from an electron gun embedded in a cathode ray tube and collides with a fluorescent surface in front, and deflects the electron beam horizontally and vertically to display a predetermined image on the fluorescent surface. It requires horizontal and vertical deflection signals.

Therefore, a horizontal output circuit and a vertical output circuit are provided to generate horizontal and vertical deflection signals and deflect electron beams according to horizontal and vertical synchronizing signals, and to operate a high voltage generation circuit with a horizontal pulse signal output from the horizontal output circuit. Supplying high pressure to the pipe.

The monitor uses an SMPS circuit to supply a stable level of operating power to each part including an image processing circuit, a high voltage generating circuit, a vertical deflection circuit, and a horizontal deflection circuit. The SMPS circuit converts an input AC power into a DC power, switches the DC power according to a pulse width modulation (PWM) signal, and then converts the AC power into a DC power to supply operating power to the load. By determining the level and adjusting the switching operation, the load is always supplied with a stable level of operating power.

In addition, the monitor may adjust the resolution of the image to be displayed, such as 640 × 480, 800 × 600 and 1024 × 768 according to the program and / or taste that the user operates, the frequency of the horizontal pulse signal is variable according to the resolution Of course, the level of the operating power supplied to each part is also variable, and the horizontal pulse signal generated in the horizontal output circuit is fed back to the PWM controller of the SMPS circuit so that the PWM controller generates the PWM signal in synchronization with the horizontal pulse signal.

1 is a conventional horizontal pulse signal supply circuit diagram. As shown therein, the AC power source AC is connected to the ground capacitor C11 through the bridge diode BD to form a power source unit 100 for converting the AC power source AC to the DC power source. The output terminal is connected to the power supply terminal of the PWM control unit 110 and is connected to the collector of the switching transistor Q1 through the primary coil ST11 of the switching transformer ST. The PWM output terminal of 110 is connected.

The switching transformer ST is provided with a plurality of secondary coils ST21 to ST2N, and the plurality of secondary coils ST21 to ST2N are connected to the ground capacitors C121 to C12N through diodes D11 to D1N, respectively. And a plurality of rectifiers 121-12N for converting an AC power source into a DC power source and supplying operating powers B1 +, B2 +, ..., BN +, and one rectifier part of the plurality of rectifiers 121-12N. For example, the output terminal of the rectifier 12N is connected to the feedback terminal of the PWM control unit 110 through the output power supply feedback unit 130.

The output terminal of the horizontal driving circuit 141 is connected to the base of the horizontal output transistor Q2, and the collector of the horizontal output transistor Q2 is connected to the diode D12 and the resistor (the output terminal of the operation power driver 142 connected in parallel). A horizontal deflection coil HDY, a horizontal transformer HT, and a ground capacitor C13 connected to the output terminal of the operating power driver 142 and connected in series with R11) C14) is connected to constitute a horizontal output circuit 140. The primary coil SY11 of the synchronization signal detection transformer SYT is connected to the horizontal deflection coil HDY and the horizontal transformer HT, and the secondary coil SY12 of the synchronization signal detection transformer SYT is generated at high pressure. It is connected to the input terminal of the circuit 150 and is connected to the PWM control unit 110 through a synchronous signal voltage drop transformer (SDT).

In the conventional horizontal pulse signal supply circuit configured as described above, when AC power is input by turning on a power switch (not shown), the input AC power AC is a bridge diode BD of the power supply unit 100. The bridge rectification is performed by the capacitor C11, smoothed by the condenser C11, converted into DC power, and then applied to the PWM control unit 110 and to the primary coil ST11 of the switching transformer ST.

In such a state, the PWM controller 110 generates a PWM signal having a predetermined period and is applied to the base of the switching transistor Q1, so that the switching transistor Q1 is repeatedly turned on and off according to the PWM signal, and the switching transistor Q1 ), The DC power applied to the primary coil ST11 of the switching transformer ST is switched and guided to the plurality of secondary coils ST21 to ST2N of the switching transformer ST. The power source guided to the plurality of secondary coils ST21 to ST2N of the switching transformer ST is rectified through the diodes D11 to D1N of the plurality of rectifiers 121 to 12N, and is directly connected by the ground capacitors C121 to C12N. The monitor is operated normally by converting to power and supplying operating powers B1 + to BN + to each part of the monitor, and output power of the rectifying unit 12N is output to the PWM control unit 110 through the output power feedback unit 130. Feedback.

Then, the PWM control unit 110 is a signal fed back from the output power supply feedback unit 130, and determines the level of the operation power sources B1 + to BN + outputted by the plurality of rectifiers 121 to 12N, and the PWM signal according to the determined level. By controlling the width of the circuit, stable operating power sources B1 + to BN + are supplied to the load.

In this way, the horizontal driving circuit 141 of the horizontal output circuit 140 generates a horizontal pulse signal synchronized with the horizontal synchronizing signal in a state in which the operating power supply B1 + to BN + is supplied to each part of the monitor in the normal operation state. The horizontal pulse signal is applied to the base of the horizontal output transistor Q2. Then, the horizontal output transistor Q2 is repeatedly turned on and off, and the horizontal deflection coil HDY generates a horizontal deflection signal as the horizontal output transistor Q2 is turned on and off to deflect the electron beam horizontally.

In this state, the horizontal pulse signal of the horizontal output circuit 140 is detected by being guided from the primary coil SY11 of the sync signal detecting transformer SYT to the secondary coil SY12, and the detected horizontal pulse signal is a high voltage generating circuit. Input to 150 to generate a high voltage and supply to the cathode ray tube, and the detected horizontal pulse signal is voltage is dropped through the synchronization signal voltage drop transformer (SDT) and then input to the PWM control unit 110. Then, the PWM controller 110 generates a PWM signal in synchronization with the cycle of the input horizontal pulse signal and controls the operation power B1 + to BN + of an appropriate level according to the resolution to be supplied to the load.

However, the above-described conventional technique uses a separate sync signal voltage drop transformer (SDT) to input the horizontal pulse signal detected by the sync signal detection transformer (SYT) to the PWM controller 110. That is, the voltage of the horizontal pulse signal detected by the sync signal detecting transformer SYT is about 300 V or more, and the horizontal pulse signal of the high voltage is converted into the PWM control unit 110 as the sync signal voltage drop transformer SDT. The voltage is reduced to an appropriate level and input to the PWM control unit 110.

Therefore, the production cost of the product increases due to a separate sync signal drop transformer (SDT), and when designing a monitor, it is necessary to secure an area for fixing the sync signal drop transformer (SDT). There was this.

Accordingly, an object of the present invention is to use a synchronization signal generating transformer to draw a low voltage horizontal pulse signal from a transformer for generating a synchronization signal in a horizontal output circuit and supply it to an SMPS circuit without using a separate synchronization signal voltage drop transformer. To provide a supply circuit.

1 is a conventional horizontal pulse signal supply circuit diagram,

2 is a horizontal pulse signal supply circuit diagram of the present invention.

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

100: power supply unit 110: PWM control unit

121 to 12N: rectifier 130: output power feedback

140: horizontal output circuit 150: high voltage generating circuit

SYT: Transformer for synchronizing signal detection SYT11: Primary coil

SYT12: Secondary Coil SYT13: Third Coil

According to the synchronization signal supply circuit of the present invention for achieving this object, the power supply unit for converting AC power into DC power source, the switching transistor switched in accordance with the PWM signal, the output power of the power supply unit in accordance with the switching of the switching transistor primary coil A switching transformer for inducing a plurality of secondary coils in a plurality, a plurality of rectifiers for supplying operating power to a load by converting the power induced by the plurality of secondary coils of the switching transformer into direct current power, and generating a horizontal deflection signal according to a horizontal pulse signal A monitor including a horizontal output circuit and a horizontal pulse signal detected by the horizontal output circuit to operate a high voltage generating circuit and input to the PWM control unit, wherein the monitor is provided with a transformer for detecting a synchronous signal. Horizontal pulse signal of the voltage level required by the PWM control unit Comprising a tertiary coil for inducing integrally, and is characterized in that the horizontal pulse signal induced in the tertiary winding adapted to be directly input to the PWM controller.

Hereinafter, the synchronization signal supply circuit of the present invention will be described in detail with reference to the accompanying drawings of FIG. 2, where the same reference numerals are assigned to the same parts as in the prior art.

2 is a horizontal pulse signal supply circuit diagram of the present invention. As shown in the drawing, the present invention is integrally provided with a third-order coil SY13 for inducing a horizontal pulse signal having a voltage level required by the PWM controller 110 in the sync signal detecting transformer SYT. The horizontal pulse signal induced by the cha coil SYT13 is configured to be directly input to the PWM controller 110.

According to the present invention configured as described above, when the horizontal output circuit 140 operates to generate a horizontal deflection signal, a horizontal pulse signal is applied to the primary coil SYT11 of the synchronous signal detecting transformer SYT so that the secondary coil SY12 and 3 may be applied. It is derived from charcoal SY13.

The horizontal pulse signal of the high voltage level induced by the secondary coil SY12 of the sync signal detecting transformer SYT is inputted to the high voltage generating circuit 150 to generate a high voltage and is supplied to the cathode ray tube, and to detect the sync signal detecting transformer. The horizontal pulse signal of the low voltage level induced by the third coil SY13 of SYT is directly input to the PWM controller 110.

Then, the PWM control unit 110 of the signal fed back from the output power feedback unit 130 in synchronization with the horizontal pulse signal of the low voltage level input from the tertiary coil (SYT13) of the sync signal detection transformer (SYT). The switching transistor Q1 is switched by outputting a PWM signal having a width corresponding to the level, and the load is supplied with an operating power of a predetermined level according to the resolution of the screen.

As described above, according to the present invention, a third coil is provided in the synchronizing signal generating transformer for generating the synchronizing signal in the horizontal output circuit without using a separate synchronizing signal voltage drop transformer and a horizontal pulse signal having a low voltage. By drawing and supplying to the PWM control unit, there are various effects such as reducing the production cost of the product and simplifying the design.

Claims (1)

A power supply unit for converting an AC power source to a DC power source, a switching transistor switched according to a PWM signal, a switching transformer for guiding output power of the power source unit from a primary coil to a plurality of secondary coils according to the switching of the switching transistor, and a plurality of the switching transformers A plurality of rectifiers for converting a power source induced by a secondary coil into a DC power source and supplying operating power to a load, a horizontal output circuit generating a horizontal deflection signal according to a horizontal pulse signal, and detecting a horizontal pulse signal from the horizontal output circuit A monitor having a transformer for synchronizing signal detection for operating a high voltage generating circuit and inputting the PWM control unit, The synchronizing signal detecting transformer is integrally provided with a tertiary coil for inducing a horizontal pulse signal having a voltage level required by the PWM control unit, and the horizontal pulse signal induced by the tertiary coil is directly input to the PWM control unit. A synchronization signal supply circuit, characterized in that configured.