KR870000999Y1 - High voltage stabilized circuit - Google Patents

Abstract

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Description

High pressure stabilization circuit

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

2 is a circuit diagram showing the configuration of an embodiment of the present invention.

3 is a circuit diagram showing the configuration of the first modified embodiment of the embodiment of the present invention.

4 is a waveform diagram showing the relationship between flyback pulses in the first modified example of the first embodiment of the present invention.

5 is a circuit diagram showing the configuration of the second modified embodiment of the embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: first horizontal deflection circuit 2 ′: second horizontal deflection circuit

14´: Flyback transformer 15: Primary winding

16: secondary winding 25: potentiometer

26: smoothing capacitor

The present invention relates to a high pressure stabilization circuit in a television receiver.

There is a conventional high pressure stabilization circuit having a first horizontal deflection circuit for driving a horizontal deflection yoke and a second horizontal deflection circuit for generating a correction pulse for high pressure stabilization.

This high voltage stabilization circuit is a direct current capacitor (7) connected in series with the horizontal output transistor (3), the damper diode (4), the resonant capacitor (5), and the horizontal deflection yoke (6) as shown in FIG. A first horizontal deflection circuit 1 for supplying a horizontal retrace pulse to the primary winding 15 of the flyback transformer 14, the transistor 9, the damper diode 10, and the resonant capacitor 11. , A second yoke 12 and a DC blocking capacitor 13 connected in series with the dummy yoke 12 and connected to the low pressure side of the secondary winding 16 of the flyback transformer 14. The voltage of the bleeder resistor 23 for detecting the secondary winding output voltage of the horizontal deflection circuit 2 and the flyback transformer and the DC power supply 19 for supplying the primary winding 15 is the bleeder resistor 23. The power supply voltage control circuit 20 supplies the power supply voltage of the second horizontal deflection circuit 2 to be controlled by the output of the power supply. 17 is a tertiary winding of the flyback transformer 14 and generates a low voltage output 22.

In addition, the rectified voltage of the voltage of the mid-tab of the secondary winding 16 of the flyback transformer 14 was divided and used as the focal voltage output 24.

When the horizontal drive pulse 18 is supplied to the conventional high pressure stabilization circuit configured as described above, the first horizontal deflection circuit 1 drives the horizontal deflection yoke 6 and at the same time the resonant capacitor 5 and the horizontal return period. The flyback pulse voltage V _P1 resonated by the horizontal deflection yoke 6 is generated in the secondary winding 16 through the primary winding 15 to generate the anode voltage of the CRT.

In this case, since a constant DC voltage is supplied from the DC power supply 19 to the first horizontal deflection circuit 1, there is no change in the flyback pulse voltage V _P1 , and the output voltage of the secondary winding 16 is reduced. There is no change.

The second horizontal deflection circuit 2 is driven by the horizontal drive pulse 18, and the flyback pulse voltage V _P2 resonated by the resonance capacitor 11 and the dummy yoke 12 during the horizontal return period. The flyback pulse voltage V _P2 is supplied to the low voltage side of the secondary winding 16.

The flyback pulse voltage (V _P2 ) Is displayed.

V _CC denotes the voltage supplied through the control circuit 20, L _D denotes the inductance of the dummy yoke 12, C _r2 denotes the capacitance of the resonant capacitor 11, and tH denotes the horizontal deflection period (63.5 μs). Doing. Therefore, the flyback pulse voltage V _P2 can be changed by changing V _CC .

When the luminance of the CRT (not shown) rises and the load current of the secondary winding 16 increases, the output voltage 21 of the secondary winding 16 decreases.

The decrease in the output voltage 21 of the secondary winding 16 is detected by the bleeder resistor 23 and the control circuit 20 increases the DC voltage supplied to the second horizontal deflection circuit 2. Accordingly, the voltage of the flyback pulse voltage V _P2 supplied to the secondary winding 16 increases by a decrease of the output voltage 21 of the secondary winding 16, thereby outputting the output voltage 21 of the secondary winding 16. The decrease in) is compensated for. On the contrary, if the output voltage 21 of the secondary winding 16 increases, this increase is detected by the bleeder resistor 23 and the control circuit 20 supplies the DC voltage supplied to the second horizontal deflection circuit 2. Lowers. Therefore, the voltage of the flyback pulse voltage V _P2 supplied to the secondary winding 16 decreases by an increase of the output voltage 21 of the secondary winding 16, thereby outputting the output voltage 21 of the secondary winding 16. The increase of is compensated for so that the output voltage 21 of the secondary winding 16 is kept constant so that the high voltage is stabilized.

However, the focus control voltage obtained by dividing the voltage of the tap in the middle of the secondary winding (hereinafter only referred to as the focus voltage) becomes overcompensated because one end of the voltage divider circuit is grounded, which causes deterioration in focus tracking characteristics. As a result, there was a defect such as deterioration in focus at high brightness.

The present invention has been made in view of the above-described drawbacks, and an object of the present invention is to provide a high voltage stabilization circuit which solves the drawbacks by applying a pulse voltage from the second horizontal deflection circuit 2 to one end of the voltage divider resistor for obtaining a focus voltage. do.

Next, the present invention will be described by way of examples.

2 is a block diagram showing the configuration of one embodiment of the present invention.

In one embodiment of the present invention shown in FIG. 2, the same components as those of the high voltage stabilization circuit of the conventional example shown in FIG. 1 are denoted with the same reference numerals.

In one embodiment of the present invention, the rectified voltage of the tap voltage is supplied to one end of the potentiometer 25 in the middle of the secondary winding 16 of the flyback transformer 14 'so that the other end of the potentiometer 25 is second horizontal. It is configured to connect the horizontal retrace pulse generating end of the deflection circuit 2 to supply the horizontal retrace pulse of the second horizontal deflection circuit 2 to the other end of the potentiometer 25. A capacitor 26 for braiding is connected to both ends of the potentiometer 25.

The operation of one embodiment of the present invention configured as described above will be described.

The flyback pulse V _P1 generated by the first horizontal deflection circuit 1 is boosted and rectified by the flyback transformer 14 'to become an output voltage 21 as an anode voltage. Here, when this output voltage 23 falls, it will be detected by the high voltage | voltage detection bleeder resistor 23. As shown in FIG.

This detection signal is applied to the control circuit 20 to increase the voltage of the flyback pulse V _P2 generated in the second horizontal deflection circuit 2. The raised flyback pulse V _P2 is applied to the low voltage side of the secondary winding 16 of the flyback transformer 14 'and operates to keep the output voltage 21 as the anode voltage constant.

On the other hand, the raised flyback pulse (V _P2 ) is applied to the other end side of the potentiometer 25 and the voltage of the flyback pulse (V _P2 ) is applied to both ends of the braiding capacitor (26) and is electrically canceled. The charge amount of the smoothing capacitor 26 is the same as when the flyback pulse V _P2 is not applied. Therefore, even if the flyback pulse V _P2 changes, the focus voltage output 24 becomes constant and the focus trouble error at the time of high voltage stabilization is improved.

Next, a first modified embodiment of the embodiment of the present invention will be described.

3 is a block diagram showing the configuration of the first modified embodiment of the first embodiment of the present invention.

In the first modified embodiment, the same components as those of the high voltage stabilization circuit in the first embodiment of the present invention shown in FIG. 2 are denoted with the same reference numerals.

In one embodiment of the present invention, the transistor 9 shown in FIG. 2 is removed, and the anode is connected to the generating end of the flyback pulse voltage V _P2 of the second horizontal deflection circuit 2 '. The cathode is configured to connect the diode 30 connected to the collector of the transistor 3 of the first horizontal deflection circuit 1 so as to switch the diode 30 by the collector output to the transistor 3.

On the other hand, the width T _r1 of the flyback pulse output from the first horizontal deflection circuit 1 and the flyback pulse voltage V _P1 are the widths of the flyback pulse output from the second horizontal deflection circuit 2 ′. T _r2 and the flyback pulse voltage V _P2 are set at V _P1 > V _P2 and T _r1 > T _r2 as shown in FIG. 4.

Where the width of the flyback pulse (T _r1 ) (L _y is the inductance of the horizontal deflection yoke 6, C _r1 is the capacitance of the resonant capacitor 5), and T _r2 is Is displayed.

Therefore, the conditions of V _P1 > V _P2 and T _r1 > T _r2 can be set by setting the horizontal deflection yoke 6 and the resonant capacitor 5, the dummy yoke 12, and the resonant capacitor 11. Further, the rectified voltage of the tap voltage is supplied to one end of the potentiometer 25 in the middle of the secondary winding 16 of the flyback transformer 14 'so that the other end of the potentiometer 25 is the second horizontal deflection circuit 2'. Is connected to the horizontal retrace pulse generating end of the second retarder 25 to supply the horizontal retrace pulse of the second horizontal deflection circuit 2 'to the other end of the potentiometer 25. A smoothing capacitor 26 is connected to both ends of the potentiometer 25.

In the first modified embodiment configured as described above, by supplying the horizontal drive pulse 18, the first horizontal deflection circuit 1 generates the flyback pulse voltage V _P1 , and the flyback pulse voltage V _{P 1} ) is boosted by the flyback transformer 14. This boosted flyback pulse voltage V _P1 is rectified and supplied as the anode voltage of the CRT. On the other hand, the diode 30 is turned on and off by the output of the transistor 3 so that the second horizontal deflection circuit 2 'generates the flyback pulse voltage V _P2 . On the other hand, the output voltage of the secondary winding 16 is detected by the bleeder resistor 23, and by the detection output of the bleeder resistor 23, the control circuit 20 is connected to the second horizontal deflection circuit 2 '. Control DC power supply voltage. Now, for example, when the output voltage of the secondary winding 16 increases, the control circuit 20 reduces the DC power supply voltage of the second horizontal deflection circuit 2 '.

Due to the decrease in the DC power supply voltage of the second horizontal deflection circuit 2 ', the output flyback pulse voltage V _P2 of the second horizontal deflection circuit 2' is lowered to keep the secondary voltage constant. When the output voltage 21 of the secondary winding 16 decreases, the control circuit 20 increases the DC power supply voltage of the second horizontal deflection circuit 2 '. By the increase of the DC power supply voltage of the second horizontal deflection circuit 2 ', the output flyback pulse voltage V _P2 of the second horizontal deflection circuit 2' is increased and the output voltage of the secondary winding 16 is increased. Keep 21 constant.

In addition, as in the case of the first embodiment of the present invention, the flyback pulse V _P2 generated in the second horizontal deflection circuit 2 'is applied to the other end of the potentiometer 25 so that the flyback is provided at both ends of the smoothing capacitor 26. Even when the voltage of the pulse V _P2 is applied to make it canceled and the flyback pulse V _P2 changes, the focus voltage output 24 becomes constant and the tracking error of focus tracking at the time of high voltage stabilization is improved.

However, the flyback pulse voltage (V _P1) and a pulse width of the first horizontal deflection circuit 1 in the (T _r1) is a flyback pulse voltage (V _P2) and a pulse width of the second bias circuit (2 ') of the (T _Since it is larger than _r2 ), the diode 30 is always in the opposite bias state.

Therefore, the flyback pulses of the first horizontal deflection circuit 1 are not mutually divided between the flyback pulses of the second horizontal deflection circuit 2 '.

In addition, in the first variation of the present embodiment, the DC voltage of the second horizontal deflection circuit 2 'is controlled by the control circuit 20, but instead of the resonance capacitor 11 or the dummy yoke 12, A controllable inductor, such as a saturable reactor, may be connected to the in series to control the controllable inductor. The diode 30 may be one or more diodes, or the transistor 3 may use another switch element instead of the bipolar transistor. Further, in the first modified embodiment, since the horizontal transistor 9 of the second horizontal deflection circuit 2 is not required and the diode 30 is used instead, the volume is small and the space factor is improved.

Next, a second modified embodiment of the embodiment of the present invention will be described.

5 is a block diagram showing a configuration in the second modified embodiment of the embodiment of the present invention.

In the second modified embodiment, in the high voltage stabilization circuit shown in the first modified embodiment shown in FIG. 3, the output flyback pulse of the second horizontal deflection circuit 2 'is connected through the coupling capacitor 24. As shown in FIG. The integrating capacitor 27, the integrating capacitor 27, and the DC power supply 19 are connected to the low voltage side of the secondary winding and connected to the low voltage side of the secondary winding 16 through the diode 25 in the reverse flow stop. A current detecting circuit 28 for an automatic luminance limiter (hereinafter referred to as an ABL) that serves as a resistor 28 connected therebetween is provided. The other end of the width tension meter 25 is connected to the output terminal of the second horizontal deflection circuit 2 ', that is, the connection point between the resonant capacitor 11 and the dummy yoke 12.

In the second modified embodiment configured as described above, the variation of the output flyback pulse from the second horizontal deflection circuit 2 'is supplied to the low voltage side of the secondary winding 16 through the coupling capacitor 24. do. Therefore, the operation of the high pressure stabilization is the same as that of the first modified embodiment of the present invention, and the flyback pulse transformer 14 is applied because the output flyback pulse from the second horizontal deflection circuit 2 'is applied through the coupling capacitor 24. High pressure can be stabilized without affecting other windings

In addition, as in the case of the first modified embodiment of the present invention, the focus voltage output 24 has a constant focus voltage output 24 even when the flyback pulse V _P2 is changed, and the focus tracking at the time of high voltage stabilization is focused. Tracking error will be improved. The change in the cathode tube current is shown as a change in the primary current of the flyback transformer 14, and the change in the primary current is shown as a change in the voltage drop of the resistor 28 '. Therefore, when the anode current increases, the voltage drop of the resistor 28 'increases, thereby lowering the voltage of one end of the resistor 28', that is, the output terminal 29 of the current detection circuit 28 for ABL, and increasing the anode current. Is detected.

On the contrary, when the anode current decreases, the voltage drop of the resistor 28 'decreases, and the voltage of the output terminal 29 of the current detection circuit 28 for ABL increases, so that the decrease in the anode current is detected. The output of the current detection circuit 28 for the ABL is connected to the contrast adjustment circuit of the video signal circuit or the control circuit of the brightness control circuit, and the current detection circuit 28 for the ABL is increased when the anode current increases more than necessary. By suppressing the brightness of the CRT by the output of), it acts to suppress the increase of the anode current.

As described above, current detection for ABL is also easily performed. In the case where the integral capacitor 27 is omitted, the operation of the ABL becomes the average value ABL when the integral capacitor is connected, which is a peak ABL.

In addition, in this second modified embodiment, the volume is small because the diode 30 is used instead of the horizontal transistor 9 of the second horizontal deflection circuit 2 as in the case of the first modified embodiment. And the space factor is improved.

In addition, in the above-described embodiment of the present invention, the first modified embodiment and the second modified embodiment thereof, the case of a television receiver has been described, but it may be a video camera, and the first embodiment, the first and second modified embodiments, and the like. It can be configured similarly.

As described above, according to the present invention, the high voltage is applied to the low voltage side of the first horizontal deflection circuit for supplying the horizontal retrace pulse to the primary winding of the flyback transformer and the secondary winding of the flyback transformer for supplying high voltage to the CRT. A second horizontal deflection circuit for supplying the horizontal retrace pulse for stabilization, and a potentiometer to which one end is connected to the middle tab of the secondary winding and the horizontal retrace pulse output from the second horizontal deflection circuit is supplied to the other end thereof. By providing a potentiometer for smoothing connected in parallel with the potentiometer and setting the output voltage of the potentiometer as the focus control voltage, deterioration of the focus tracking characteristic can be improved without deteriorating the focus even in high luminance and the like.

Claims (1)

Second winding of the first horizontal deflection circuit 1 for supplying the horizontal retrace pulse to the primary winding 15 of the flyback transformer 14 'and the flyback transformer 14' for supplying high pressure to the CRT anode. One end is connected to the second horizontal deflection circuit 2 'which supplies the horizontal retrace pulse for stabilizing the high voltage to the low voltage shaft of 16 and the middle tap of the secondary winding 16, and the second end is connected to the other end. A potentiometer 25 to which the horizontal retrace pulse outputted from the horizontal deflection circuit 2 'is supplied, and a smoothing capacitor 26 connected in parallel to the potentiometer 25, and outputs the output voltage of the potentiometer 25. A high pressure stabilization circuit characterized by a focus control voltage.