KR19980031638A - Monitor high voltage feedback stabilization circuit - Google Patents

Abstract

The present invention relates to a high-pressure feedback stabilization circuit of a monitor that is capable of preventing variations in the picture tube screen size due to a decrease in the anode voltage when the anode current of the picture tube (CRT) increases. In the anode voltage supply circuit of the water pipe, in which the AC voltage output from the secondary winding is converted into a DC voltage by the rectifying diode D21 and the smoothing capacitor C21 and supplied to the anode of the water pipe, the anode voltage is applied to the anode of the water pipe. An anode voltage detecting means 20 for detecting a voltage to be made; PWM control means 22 for outputting a PWM control signal based on the detected voltage from the anode voltage detecting means 20; And voltage control means 24 for controlling the emitter voltage of the horizontal output transistor TR2 by the PWM control signal from the PWM control means 22.

Description

A high voltage feedback stabilization circuit in a monitor

The present invention relates to a high-voltage feedback stabilization circuit of the monitor, and more particularly to a high-pressure feedback stabilization circuit of the monitor to be able to prevent the fluctuation of the water pipe screen size due to the decrease of the anode voltage when the anode current of the water tube (CRT) increases. will be.

In general, the power supply circuit of the monitor performs the proper supply of the voltage required for each part of the monitor. Related to this technology, SMPS (Switched) is smaller, lighter and more efficient than the linear power supply. The switching power supply, called Mode Power Supply, is rapidly developing.

1 is a circuit diagram illustrating a high voltage feedback stabilization circuit of a general monitor. As shown, the high pressure feedback stabilization circuit is composed of a high pressure feedback stabilization unit 1 and a flyback transformer 2. The flyback transformer 1 converts an alternating voltage output from the secondary winding into a DC voltage to supply a rectifier diode D1 for supplying to the anode of the water pipe and a high voltage for supplying the anode of the water pipe anode. The resistors R1, R2, R3, R4, and R5 supplied at the feedback voltage of the feedback stabilization part 1 are comprised.

The high voltage feedback stabilization unit 2 includes an OP amplifier in which a non-inverting input terminal (+) receives a feedback voltage and an inverting input terminal (−) receives a feedback input of an output voltage; An error amplifier (EA) for outputting an error signal by the output signal of this OP amplifier; A PWM controller (PWM) for adjusting the on / off time of the PWM control signal by the output signal of the error amplifier EA; A gate terminal is connected to the PWM control unit via a resistor R11, a drain terminal is connected to a switching power supply SMPS, and a DC power supply voltage, for example, 200 V is applied from the power supply SMPS, and a source terminal is grounded. A transistor (FET) and; One end is connected in parallel between the source terminal and the ground of the power transistor (FET), the other end is grounded through a capacitor (C5) and consists of a coil (L2) connected to the primary winding of the flyback transformer (2). .

On the other hand, looking at the operating principle of the flyback transformer (2), in the flyback transformer (2) B ⁺ voltage supplied from the high-pressure feedback stabilizer (1) is input to the primary winding is stepped up. Therefore, the AC voltage output from the secondary winding of the flyback transformer 2 is converted into a DC voltage by the rectifying diode D1 and then supplied to the anode of the water pipe, and the high voltage supplied to the anode is the resistance R1. , R2, R3, R4, R5) is properly voltage-divided and supplied to the screen, focus, high-pressure feedback stabilizer (1).

In addition, the high voltage feedback stabilization unit 1 receives the feedback voltage Vfb from the flyback transformer 2, and the feedback voltage Vfb is input to the non-inverting input terminal (+) of the OP amplifier to set the voltage. After the comparison with the output signal, a predetermined comparison signal is output. The error amplifier EA is driven by the comparison signal to control the PWM controller PWM.

That is, when the signal input to the non-inverting input terminal (+) of the OP amplifier is greater than the set voltage, the PWM control unit PWM outputs a pulse width modulation (PWM) control signal having a short on state, When the signal input to the non-inverting input terminal (+) of the OP amplifier is smaller than the set voltage, the PWM controller PWM outputs a long PWM control signal to the gate terminal of the power transistor FET.

At this time, the on / off state of the power transistor FET is controlled by the PWM control signal output from the PWM controller PWM. That is, when the power transistor (FET) transitions to the on state after maintaining the off state for a predetermined time by a PWM control signal, the power current supplied from the switching power supply (SMPS) through the drain stage is DC through the source stage To the primary winding of the / DC converter (DDC).

In addition, when the PWM control signal having a short on state is supplied to the gate terminal of the power transistor FET, the on state of the power transistor FET is shortly adjusted so that the input voltage and the output voltage of the flyback transformer 2 are adjusted. The size of will change. When the PWM control signal with a long on state is supplied to the gate terminal of the power transistor FET, the on state of the power transistor FET is long controlled.

Therefore, in the high voltage feedback stabilization unit 1, the voltage of the non-inverting input terminal (+) of the OP amplifier is changed by the load change, so that the high voltage is stabilized. For example, when the load current increases and the anode voltage increases, the feedback voltage Vfb output from the flyback transformer 2 increases to input voltage of the non-inverting input terminal (+) of the OP amplifier. As a result of this increase, the output of the error amplifier EA is lowered, and then a PWM control signal having a short on-state is output, thereby lowering the B ⁺ voltage. As such, when the B ⁺ voltage is lowered, the high pressure generated from the secondary winding of the flyback transformer 2 increases.

At this time, the AC voltage output from the secondary winding of the flyback transformer 2 is converted into a DC voltage by the rectifier diode D1 and then supplied to the anode of the water pipe, and the high voltage supplied to the anode is a resistor R1. , R2, R3, R4, and R5 are properly distributed and supplied to the high pressure feedback stabilizer 1. Thereafter, the AC voltage output from the secondary winding of the flyback transformer 2 is rectified through the rectifying diode D1.

On the other hand, the power supply voltage from the switching power supply (SMPS) is stabilized to B ⁺ voltage through the high-pressure feedback stabilization unit 1 is input to the flyback transformer (2) to be boosted.

Therefore, the AC voltage output from the secondary winding of the flyback transformer 2 is converted into a DC voltage by the rectifying diode D1 and then supplied to the anode of the water pipe. In addition, the high pressure supplied to the anode is properly voltage-divided through the voltage distribution resistors R1, R2, R3, R4, and R5 to be supplied to the screen, the focus, the high-pressure feedback stabilization unit 1, and the like of the water pipe.

At this time, the voltage supplied to the high pressure circuit, a horizontal output circuit from the switching power (SMPS) is a voltage that the voltage level in accordance with the horizontal frequency variations, for example, B ⁺ voltage is required to stabilize the high voltage feedback unit (1). That is, the larger the size of the high pressure, the smaller the size of the picture tube screen, so that the size of the high pressure must always be constant so that the picture tube screen is always constant regardless of the horizontal frequency.

Therefore, the high voltage feedback stabilizer 1 serves to supply the flyback transformer 2 with a B ⁺ voltage proportional to the horizontal frequency in order to maintain a high voltage. In addition, the high pressure feedback stabilization unit 1 serves to prevent the distortion of the screen from occurring due to the change in the high pressure according to the load.

That is, the high voltage feedback stabilization unit 1 receives the feedback voltage Vfb and compares the feedback voltage with the set voltage, and when the feedback voltage Vfb is greater than the set voltage, the power supply voltage supplied from the switching power supply SMPS is lowered. When the feedback voltage (Vfb) is less than the set voltage, the power supply voltage supplied from the switching power supply (SMPS) is raised to increase the primary side of the flyback transformer (2). Supply to the winding. Thereafter, the magnitudes of the input voltage and the output voltage of the flyback transformer FBT are stabilized.

In addition, the flyback transformer 2 is also connected to the load of the water pipe, so that the high-pressure feedback stabilization unit 1 is able to adjust the B ⁺ voltage by the high and low beam current. That is, when the beam current increases and the anode voltage, for example, the high voltage, increases, the feedback voltage Vfb increases, thereby lowering the B ⁺ voltage and lowering the high voltage generated from the flyback transformer 2.

On the other hand, when the beam current decreases and the anode voltage falls, the feedback voltage Vfb decreases to increase the B ⁺ voltage, thereby increasing the high voltage generated from the flyback transformer 2.

As described above, when the beam current is changed by the change of the screen brightness, the high pressure of the anode is changed to change the size of the picture tube screen. Therefore, there is a need for a stabilization circuit that maintains the high pressure of the anode constant.

Accordingly, the present invention is to solve the above problems, to provide a high-voltage feedback stabilization circuit of the monitor to be able to prevent the fluctuations in the size of the water pipe screen by the decrease of the anode voltage when the anode current of the water pipe (CRT) increases. Its purpose is to.

In order to achieve the above object, the present invention provides an anode voltage supply of a water pipe in which an AC voltage output from the secondary winding of the flyback transformer is converted into a DC voltage by a rectifying diode and a smoothing capacitor and supplied to the anode of the water pipe. A circuit comprising: anode voltage detecting means for detecting a voltage applied to an anode of said water pipe; PWM control means for outputting a PWM control signal based on the detected voltage from said anode voltage detecting means; And voltage control means for controlling the emitter voltage of the horizontal output transistor by the PWM control signal from the PWM control means.

In the present invention configured as described above, the high-pressure feedback stabilization circuit is composed of an anode voltage detector, a PWM controller, and a voltage controller, so that the voltage B is proportional to the decrease of the anode voltage when the anode current of the water pipe increases. Compensation for the ^positive voltage can prevent variations in the picture tube screen size.

1 is a high voltage feedback stabilization circuit diagram of a general monitor;

2 is a high voltage feedback stabilization circuit diagram of a monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

1: high pressure feedback stabilizer, 2: flyback transformer,

10: horizontal oscillation unit, 12: horizontal drive unit,

14: horizontal output unit, 20: anode voltage detection unit,

22: PWM controller, 24: voltage controller.

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

2 is a high voltage feedback stabilization circuit diagram of a monitor according to the present invention. As shown, the circuit consists of horizontal deflection circuits 10, 12, 14 and high voltage feedback stabilization circuits 20, 22, 24. The horizontal deflection circuit includes a horizontal oscillation unit 10, a horizontal driving unit 12, and a horizontal output unit 14. The high voltage feedback stabilization circuit includes an anode voltage detector 20, a PWM controller 22, and a voltage controller 24.

On the other hand, in the single deflection circuits 10, 12 and 14, the horizontal drive signal H.drive having the horizontal synchronization frequency H.sync output from the video card is transferred to the base terminal of the horizontal drive transistor TR1. When the horizontal driving transistor TR1 is turned on, the horizontal driving current is input to the base terminal of the horizontal output transistor TR2 through the horizontal driving transformer HDT.

Thereafter, the horizontal output transistor TR2 is turned on so that the B ⁺ power supply current of the flyback transformer FBT flows to the horizontal output transistor TR2 through the horizontal deflection coil HD.Y. As such, while the transistor TR2 is in the on state, the effective syringe gap of the horizontal sawtooth wave corresponds to the latter half period between syringes.

When the horizontal output transistor TR2 is suddenly turned off by the horizontal driving signal H. driver, the current accumulated in the horizontal deflection coil HD.Y is charged in the retrace capacitor RE.C. .

Therefore, when the retrace capacitor RE.C is fully charged, the capacitor is discharged again from the capacitor RE.C to the horizontal deflection coil HD.Y to accumulate current in the deflection coil HD.Y again. . In this way, the retrace period is determined by the charge and discharge periods of the retrace capacitor RE.C.

When energy is accumulated in the deflection coil HD.Y and the deflection coil voltage is applied to the forward bias voltage through the damper diode D, the damper diode D is turned on so that the deflection coil HD. The current flowing to Y) drops to zero. At this time, the interval between the syringes of the effective current of the horizontal sawtooth wave flowing through the damper diode (D) corresponds to the first half period between the syringes.

As described above, the horizontal output transistor TR2 is turned on again by the horizontal drive signal H.driver at the time when the current becomes 0, and the above process is repeated, and the sawtooth wave is moved to the horizontal deflection coil HD.Y. As the current flows, horizontal deflection is performed while horizontal scanning is performed.

On the other hand, in the high-voltage feedback stabilization circuits 20, 22, and 24, the AC voltage output from the secondary winding of the flyback transformer FBT is converted into the DC voltage by the rectifying diode D21 and the smoothing capacitor C21. Then, the high voltage supplied to the anode of the water pipe is supplied to the PWM controller 22 by voltage distribution by the resistors R30 and R31.

The anode voltage detector 20 detects a change in the high voltage applied to the water pipe anode, and the PWM controller 22 outputs a PWM control signal based on the detected voltage from the anode voltage detector 20. The voltage control unit 24 controls the emitter voltage of the horizontal output unit 14 transistor TR2 by the PWM control signal from the PWM control unit 22.

The anode voltage detector 20 is connected between the anode terminal of the water pipe and the ground, and is composed of resistors R30 and R31 for dividing the voltage of the anode terminal. In addition, the voltage controller 24 is connected to the power supply Vcc via the inductive reactance L21 and to the anode of the diode D22, and the base is connected to the PWM control unit through the resistor R32. A transistor TR3 connected to 22 and having an emitter grounded; One end is connected to the emitter of the horizontal output transistor TR2 of the horizontal output unit 14 and is connected to the cathode of the diode D22, and the other end includes a capacitor C22 grounded.

The PWM controller 22 blocks the driving current to the voltage controller 24 when the detected voltage from the anode voltage detector 20 is equal to or less than a reference voltage, and the voltage controller 24 controls the PWM controller 22. When the drive current is cut off, the emitter voltage of the horizontal output transistor TR2 is raised to Vcc by the capacitor C22.

On the other hand, the B ⁺ voltage output from the SMPS is applied to the primary coil of the flyback transformer (FBT), and the voltage induced from the secondary coil, for example, a voltage of about 25 KV, is supplied to the anode of the water pipe. In addition, the B ⁺ voltage is applied to the collector terminal of the horizontal output transistor TR2 through the primary coil of the flyback transformer FBT.

As described above, when the anode voltage of the water pipe is changed by the change of the beam current applied to the anode of the water pipe, the anode voltage detector 20 detects the changing voltage. Thereafter, the PWM controller 22 applies a detection signal from the anode voltage detector 20, for example, a control signal proportional to an increase in the anode voltage of the water pipe, to the base of the transistor TR3 of the voltage controller 24. .

At this time, the transistor TR3 is driven so that the voltage Vcc is applied to a circuit consisting of an inductive reactance L21, a collector, an emitter, and a ground of the transistor TR3, and thus, the horizontal output transistor TR2. The emitter voltage is brought to ground.

In addition, when a detection signal from the anode voltage detector 20, for example, a control signal proportional to a decrease in the anode voltage of the water pipe, is applied to the transistor TR3 of the voltage controller 24, the transistor TR3 is applied. It is not driven so that the voltage Vcc is applied to a circuit consisting of the inductive reactance L21, the diode D22, the capacitor C22, and the ground.

In this case, the voltage Vcc is applied to the capacitor C22 to decrease the emitter voltage of the horizontal output transistor TR2, thereby increasing the B ⁺ voltage of the flyback transformer FBT, thereby increasing the flyback transformer ( The secondary side water tube anode voltage of FBT is increased.

In addition, it can change and implement in various ways within the range which does not deviate from the summary of invention.

As described above, according to the present invention, the high-voltage feedback stabilization circuit includes an anode voltage detector, a PWM controller, and a voltage controller, so that a voltage proportional to the decrease of the anode voltage when the anode current of the water pipe increases. Compensation for the differential B ⁺ voltage can prevent variations in the picture tube screen size.

Claims (5)

In the anode voltage supply circuit of the water pipe in which the AC voltage output from the secondary winding of the flyback transformer (FBT) is converted into a DC voltage by the rectifying diode (D21) and the smoothing capacitor (C21) and supplied to the anode of the water pipe. , Anode voltage detecting means for detecting a voltage applied to the anode of the water pipe; PWM control means 22 for outputting a PWM control signal based on the detected voltage from the anode voltage detecting means 20; And a voltage control means (24) for controlling the emitter voltage of the horizontal output transistor (TR2) by the PWM control signal from the PWM control means (22). 2. The high voltage feedback stabilization of the monitor according to claim 1, wherein the anode voltage detecting means (20) comprises resistors (R30 and R31) for dividing the voltage of the anode terminal while being connected between the anode terminal of the water pipe and the ground. Circuit. 2. The PWM control means according to claim 1, characterized in that the PWM control means (22) blocks the drive current to the voltage control means (24) if the detected voltage from the anode voltage detection means (20) is less than or equal to a reference voltage. High-voltage feedback stabilization circuit of the monitor. The voltage control means (20) of claim 1, wherein the voltage control means (20) includes a capacitor (C22) for raising the emitter voltage of the horizontal output transistor (TR2) to Vcc when the driving current from the PWM control means (22) is interrupted. High-voltage feedback stabilization circuit of the monitor, characterized in that. 2. The voltage control means (24) according to claim 1, wherein the voltage control means (24) is connected to the power supply (Vcc) via the inductive reactance (L21), and to the anode of the diode (D22), and the base is connected to the resistor (R32). A transistor TR3 connected to the PWM control means 22, the emitter being grounded; A monitor having one end connected to the emitter of the horizontal output transistor TR2 of the horizontal output means 14 and connected to the cathode of the diode D22, the other end of which comprises a grounded capacitor C22 High pressure feedback stabilization circuit.