KR0114694Y1 - High voltage stabilizing circuits for tv - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

It is a technology that stabilizes high voltage by keeping high voltage constant as the brightness of screen changes.

2. Technical problem to be solved by the invention

Since the high voltage output is detected by the internal bleeder resistor of the high voltage output transformer (T1), a high breakdown voltage resistor is required, and the volume of the high breakdown resistor is increased so that the total volume of the high voltage output transformer increases, and the circuit is complicated and the PCB This solves the problem of increasing the board area and increasing the cost of the system.

3. Summary of Solution to Invention

In order to stabilize the high voltage without including the bleeder resistor inside the transformer, the main power input terminal for receiving the high voltage main power and the ABL terminal are connected to each other. ABL voltage detection means for detecting and switching the main power supplied through the main power input terminal; and ABL variable voltage detection means for detecting the ABL fluctuation voltage difference by receiving the main power output switching to the ABL voltage detection means; An error amplifying means for receiving and amplifying the main power in response to the ABL fluctuation voltage detected by the ABL fluctuation voltage detecting means and outputting a high voltage to output a main power supply control signal to stabilize the high voltage according to the voltage amplified from the error amplifying means; Stabilization control means and: the main output from the high pressure stabilization control means And main power output means for controlling the supply of the main power to the primary side of the high voltage output transformer by a power supply control signal.

4. Intended Use

It is used to stabilize high voltages generated from flyback transformers in televisions.

Description

TV's High Voltage Stabilization Circuit

1 is a high voltage stabilization circuit diagram of a conventional television.

2 is a high voltage stabilization circuit diagram in a television according to the present invention.

* Explanation of symbols for main parts of the drawings

R11-R18: Resistor C11-C12: Capacitor

D11-D13: Zener Diode D14: Diode

Q11-Q14: Transistor T11: Transformer for high voltage output

The present invention relates to a high voltage stabilization circuit of a television, and more particularly, to a high voltage stabilization circuit that stabilizes a high voltage by constantly maintaining a high voltage according to a change in brightness of a screen.

Generally, the CRT (Cathod Ray Tube) which is a display part of a television requires high voltage. FIG. 1 is a conventional circuit diagram for supplying a high voltage to a CRT of a television. The main power input through the first input terminal A is connected to the high voltage output transformer T1 through the main power output unit 40 formed of the transistor Q4. It is applied to the vehicle side. At this time, the transformer T1 generates a high voltage as the high voltage pulse output unit 50 including the transistor Q5, the diode D4, and the capacitor C5 is driven by the high voltage pulse input through the third input terminal C. To the ABL (Automatic Brightness Limitting) circuit through the high voltage output terminal (E). Referring to the operation of the high voltage pulse output unit 50 composed of the transistor Q5, the diode D4, and the capacitor C5, the high voltage pulse control signal is input through the third input terminal C when a high voltage is generated. Transistor Q5 is turned on. When the transistor Q5 is turned on, the current generated to the primary side of the high voltage output transformer T1 is absorbed by the capacitor C5 and the diode D4 and the vibration generated by the rapid change is absorbed in the collector of the transistor Q5. Will flow to the emitter.

When a high voltage is generated in the high voltage output transformer T1, the electron beam (ABL current) flows less when the screen is dark, so that the high voltage of the transformer T1 increases. When the high voltage output from the high voltage output transformer T1 is increased, the output high voltage applied to the bleeder resistors R16 and R17 inside the anode is increased, and this voltage is divided by the resistors R1 and R2 to be transistor Q1. Is applied to the base of. Accordingly, since the transistor Q1 is driven and the sub-power inputted through the second input terminal B is applied to one terminal of the operational amplifier IC1, the operational amplifier IC1 stabilizes the applied sub-power and outputs the stabilized output. Done. The stable voltage in the operational amplifier IC1 is adjusted according to the resistance value of the variable resistor VR1 and applied to one terminal of the comparator IC2. At this time, the comparator IC2 outputs a “high” signal because the voltage inputted through the variable resistor VR1 is higher than the voltage set by the zener diode D1 and the capacitor C2. It is applied to the base of (Q2). As a result, since the transistors Q2 and Q3 are turned on, the voltages of the base and the emitter of the transistor Q4 are reduced to be applied to the B ⁺ terminal of the high voltage output transformer T1. Therefore, the high voltage output transformer T1 outputs a high voltage so that the high voltage is kept constant.

However, when the screen is bright, the high voltage of the transformer T1 is reduced because the electron beam (ABL current) is clouded a lot. When the high voltage output from the high voltage output transformer T1 is reduced, the output high voltage applied to the bleeder resistors R16 and R17 inside the anode is lowered, and this voltage is divided by the resistors R1 and R2 to be transistor Q1. Is applied to the base. Accordingly, since the transistor Q1 is driven and the sub-power inputted through the second input terminal B is applied to one terminal of the operational amplifier IC1, the operational amplifier IC1 stabilizes the applied sub-power and outputs the stabilized output. Done. The stable voltage in the operational amplifier IC1 is adjusted according to the resistance value of the variable resistor VR1 and applied to one terminal of the comparator IC2. At this time, since the voltage inputted through the variable resistor VR1 is lower than the voltage set by the zener diode D1 and the capacitor C2, the comparator IC2 outputs a “low” signal to output the transistor through the resistor R8. It is applied to the base of (Q2). As a result, since the transistors Q2 and Q3 are turned off, the voltages of the base and the emitter of the transistor Q4 are increased to be applied to the B ⁺ terminal of the high voltage output transformer T1. Therefore, the high voltage output transformer T1 outputs a high voltage to keep the high voltage constant. Referring to the operation of the high voltage pulse output unit 50 composed of the transistor Q5, the diode D4, and the capacitor C5, which are not described herein, the high voltage pulse control signal is input through the third input terminal C when a high voltage is generated. In this case, the transistor Q5 is turned on. When the transistor Q5 is turned on, the current generated to the primary side of the high voltage output transformer T1 is absorbed by the capacitor C5 and the diode D4 and the vibration generated by the rapid change is absorbed in the collector of the transistor Q5. Will flow to the emitter.

In the conventional high voltage stabilization circuit as described above, a high voltage resistance resistor is required because the high voltage output is detected by the internal bleeder resistor of the high voltage output transformer (T1), and the volume of the high voltage resistance resistor is increased so that the total volume of the high voltage output transformer is increased. In addition, there is a problem that the cost of the system is increased by increasing the area of the PCB board because the circuit is complicated.

Accordingly, an object of the present invention is to provide a high voltage stabilization circuit for solving the above problems.

Another object of the present invention is to provide a high voltage stabilization circuit for controlling the output high voltage is stabilized according to the brightness of the screen in the television.

Still another object of the present invention is to provide a high voltage stabilization circuit capable of miniaturization by reducing the volume of a high voltage output transformer in a television.

In order to achieve the objects of the present invention, the present invention is connected to a main power input terminal for receiving a high voltage main power source, an ABL terminal, and the ABL terminal to generate a high voltage of a television, and a high electron beam current flows and a small flow. ABL voltage sensing means for sensing the ABL voltage state of the ABL terminal according to the switching and outputting the main power supplied through the main power input terminal: detecting the ABL fluctuation voltage difference by receiving the main power switched output by the ABL voltage sensing means ABL variable voltage detection means for: error amplification means for receiving and amplifying and outputting the main power in response to the ABL variable voltage detected by the ABL variable voltage detection means; High pressure stabilization control means for outputting a main power supply control signal to: And it characterized in that it consists of a main power output means for controlling the supply of the main power supply to the primary side of the transformer high voltage output by the main power supply control signal output from the control means.

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

2 is a block diagram of a high voltage stabilization circuit of a television according to the present invention, in which a portion composed of the resistors R11-R13 and the transistor Q11 serves as a means for detecting an output ABL high voltage state. The ABL voltage detecting means is connected to the ABL terminal, and detects the ABL voltage state of the ABL terminal as the electron beam current flows a lot, and switches the main power supplied through the main power input terminal to the ABL variable voltage detection means. Output In addition, the ABL variable voltage detection means includes a zener diode D11 and a variable resistor VR11 to detect the ABL variable voltage difference and adjust the voltage level when more than the set voltage is applied. The error amplifying means includes a zener diode D12, a resistor R15, and a transistor Q12, and receives the main power supply and amplifies the error amplifying voltage from the ABL variable voltage detecting means to correspond to the variable voltage. The high voltage stabilization control means includes a zener diode (D13), a transistor (Q13), a resistor (R17-R18), and a capacitor (C11) to supply a main power supply control signal to stabilize the high voltage according to the voltage amplified from the error amplifying means. Output The main power output means is composed of a resistor R16 and a transistor Q13 to receive the main power and output the main power to the primary side of the high voltage output transformer T11 by a main power supply control signal output from the high voltage stabilization control means.

The present invention will be described in detail based on the configuration of FIG. 2 described above.

First, when the screen is dark, since the ABL current flows less, the secondary high voltage of the high voltage output transformer T11 increases. When the secondary voltage of the high voltage output transformer T11 increases, the ABL output voltage is applied to the high bias voltage of the transistor Q11 through the resistor R11 through the ABL terminal 2. As a result, since the transistor Q11 is turned on, the main power is applied to the emitter through the resistors R14 and R13. At this time, the zener diode D11 is turned on since the reference set voltage is applied. Accordingly, the voltage passing through the zener diode D11 is adjusted by the variable resistor VR11, and the emitter voltage of the transistor Q12 whose level is adjusted by the variable resistor VR11 is the zener diode. Transistor Q12 is turned off because it is higher than the base voltage of transistor Q12 passing through D12. When the transistor Q12 is turned off, the main power through the resistor R15 is applied to the base of the transistor Q13 at a high bias voltage through the zener diode D13. As a result, the transistor Q13 is turned on to increase the voltage drop across the current limiting resistor R17 of the collector terminal. Accordingly, the bias voltage applied to the base of the transistor Q14 is lowered, which lowers the voltage applied to the primary side of the high voltage output transformer T11 through the emitter at the collector of the transistor Q14. Therefore, since the high voltage output to the secondary side of the high voltage output transformer T11 is lowered, the constant voltage is always maintained.

However, when the screen is bright, since the ABL current flows a lot, the secondary high voltage of the high voltage output transformer T11 is lowered. When the secondary voltage of the high voltage output transformer T11 is lowered, the ABL output voltage is applied to the low bias voltage of the transistor Q11 through the resistor R11 through the ABL terminal 2. At this time, the zener diode D11 is turned off because there is no voltage output through the transistor Q11. Since the transistor Q11 is turned off, the main power is applied to the zener diode D12 through the resistor R14. As a result, the voltage applied through the resistor R14 becomes greater than or equal to the set reference voltage to turn on the zener diode D12. When the diode D12 is turned on, an elevated bias voltage is applied to the base of the transistor Q12 so that the error amplifier transistor Q12 is turned on so that the voltage through the resistor R14 is emitted from the collector of the transistor Q12. Is output to the controller, and the level value is adjusted by the variable resistor VR11. When the transistor Q12 is turned on, the collector of the transistor Q12 is in a low voltage state, and thus the zener diode D13 is turned off. When the diode D13 is turned off, the transistor Q13 is turned off. Accordingly, when the transistor Q13 is turned off, the bias voltage applied to the base of the transistor Q14 is raised to a high state, which causes the high voltage output transformer T11 of the transistor Q14 through the emitter at the collector of the transistor Q14. The voltage applied to the primary side becomes high. Therefore, the high voltage output to the secondary side of the high voltage output transformer T11 is high, so that a constant voltage is always maintained.

Referring to the operation of the high-voltage pulse output means composed of a transistor (Q15), a diode (D14), and a capacitor (C12) not described herein, when a high voltage is generated, a high voltage pulse control signal is input through the third input terminal (C). Transistor Q15 is turned on. When the transistor Q15 is turned on, the current flowing to the primary side of the high voltage output transformer T11 is absorbed by the capacitor C12 and the diode D14 and the vibration generated by the rapid change is absorbed by the collector of the transistor Q15. It will flow stably to the emitter.

As described above, the high voltage stabilization circuit of the television according to the present invention constantly controls the secondary output high voltage of the high voltage output transformer according to the brightness of the screen, and does not use the bleeder resistor inside the high voltage output transformer. By controlling according to the present invention, the transformer for the high voltage output can be miniaturized, and the transformer for the high voltage output can be miniaturized, thereby reducing the PCB board area and reducing the cost.

Claims (4)

A high voltage stabilization circuit having a high voltage output transformer for inputting a main power and outputting a high voltage, wherein the ABL terminal is connected to a main power input terminal for receiving a high voltage main power and an ABL terminal, and a large amount of electron beam current flows and flows less. ABL voltage sensing means for sensing and outputting the ABL voltage state of the main power supplied through the main power input terminal, and ABL voltage sensing means for detecting the ABL fluctuation voltage difference by receiving the main power outputted by the ABL voltage sensing means. And means: error amplifying means for receiving and amplifying the main power in response to the ABL fluctuation voltage detected by the ABL fluctuation voltage detecting means, and: a main power supply control signal for stabilizing a high voltage according to the voltage amplified from the error amplifying means. High pressure stabilization control means for outputting: the high pressure stabilizer The output from the main power supply means controlled by a signal of the high voltage stabilizing television, characterized in that the output consists of a main power supply means for controlling the supply of the main power supply to the primary side of the high voltage output transformer circuit. The method of claim 1, wherein the ABL variable voltage detection means, a cathode is connected to the output terminal of the ABL voltage detection means, the zener diode is turned on when the switching output voltage is a predetermined voltage or more, the zener diode is turned on and supplied A high voltage stabilization circuit for a television, characterized by comprising a variable resistor for variably adjusting a voltage level. The method of claim 2, wherein the error amplifying means, a cathode is connected to the main power input terminal, the zener diode is turned on when the main power input is applied to a predetermined voltage or more, and the switch is turned on when the zener diode is turned on, And a transistor for amplifying and outputting the main power supply in accordance with the change voltage of the ABL voltage change means. A high voltage stabilization circuit having a high voltage output transformer for generating a high voltage by inputting a main power supply, comprising: a main power input terminal for receiving a high voltage main power source, a high voltage driving pulse input terminal, a high voltage output terminal for outputting a high voltage, and an ABL terminal; ABL voltage sensing means for sensing the ABL voltage state of the ABL terminal and switching output of the main power supplied through the main power input terminal as the electron beam current flows a little and flows less: a main power switched by the ABL voltage sensing means An ABL variable voltage detection means for receiving an input and detecting the ABL variable voltage; Main power supply to stabilize the high voltage according to the amplified voltage A high pressure stabilization control means for outputting a signal; a main power output means for controlling the supply of the main power to a primary side of the high voltage output transformer by a main power supply control signal output from the high pressure stabilization control means, and one of the high voltage output transformers; And a high voltage pulse output means connected to the car coil and configured to interrupt a current flowing in the primary coil of the high voltage output transformer as switched on / off by a high voltage drive pulse input through the high voltage drive pulse input terminal. TV's high voltage stabilization circuit.