JPS6338605Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention is designed to prevent malfunctions of other circuits caused by internal discharge of cathode ray tubes (hereinafter referred to as CRTs) used in television receivers, particularly color television receivers, or projection type television receivers. This relates to a malfunction prevention circuit that attempts to prevent this from occurring.

CRTs used in television receivers apply high voltage, so if there are impurities inside the CRT, internal discharge may occur during operation. As a result, the original function of the television receiver is impaired.

Conventionally, various measures have been taken to avoid this malfunction. For example, modify the ground line or use a spark gap. However, these measures
Malfunctions could not be avoided in all functions of the television receiver.

The present invention aims to indirectly detect the discharge voltage and use this detected voltage to prevent malfunction of a specific circuit. Embodiments of the present invention will be described below based on the accompanying drawings.

FIG. 1 is a block circuit diagram showing a portion of a high voltage supply circuit of a television receiver to which an embodiment of the present invention is applied. 16 is a cathode ray tube, ie, CRT, of the television receiver; 17 is a video amplifier; this amplifier amplifies the input video signal and applies it to the cathode of the CRT 16; 11 is an oscillation circuit for horizontal scanning of the CRT 16, and its output is sent to the horizontal deflection circuit 20.
and is applied to the high voltage generation circuit 12. A high-voltage output transformer for boosting the output pulse is provided at the downstream stage of this high-voltage generating circuit 12, and the boosted pulse voltage is transferred to the high-voltage rectifier 1 disposed at the downstream stage of this transformer.
4, and its output is applied to the anode of the CRT 16. Note that 15 is a resistor of the high voltage bleeder, and one end of this resistor is connected to the output side of the high voltage rectifier 14, and the other end is connected to the ground.

E ₁ is a DC wire, and 1 and 2 are voltage dividing resistors connected in series between this power source and ground.
3 is a clamping diode, and this diode is connected between the DC power source E ₂ and the connection point Q between the resistors 1 and 2. Note that the connection point Q controls the brightness (anode current) of the CRT by its voltage.
It is connected to the video amplifier 17 and also to the secondary coil of the high voltage output transformer 13 via the overcurrent detection circuit 9. Further, the capacitor 18 connected to the secondary coil of the high voltage output transformer 13 is for ripple removal.

Thus, DC power supplies E ₁ , E ₂ , resistors 1, 2,
The current A' flowing from the diode 3 through the secondary coil of the high voltage output transformer 13 is the sum of the current flowing to the high voltage bleeder resistor 15 and the anode current Ip flowing to the CRT 16, while this current A is for voltage division. A predetermined brightness automatic control voltage is applied to the video intensifier 17 via the resistors 1 and 2.

In other words, DC power supplies E ₁ , E ₂ , resistor 1,
2, the diode 3, the secondary coil of the high-voltage output transformer 13, the high-voltage rectifier 14, the CRT 16, and the video amplifier 17 form an automatic brightness control loop that operates to prevent the anode currents A and A' from increasing beyond a certain value. It consists of

A wiring diagram of the overcurrent detection circuit 9 is shown in FIG. 10 is a horizontal oscillation stop circuit arranged before the horizontal oscillation circuit 11, and this stop circuit is activated by the operating voltage signal B from the overcurrent detection circuit 9 to stop the operation of the horizontal oscillation circuit 11. Outputs a signal to Note that a specific example of the horizontal oscillation stop circuit 10 is shown in FIG. Of the circuits described so far, 9, 10, and 11 constitute a high voltage stop circuit that operates in the event of an overcurrent.

In the circuit shown in FIG. 1 which has been explained here, the high voltage stopping operation will be explained. Overcurrent detection circuit 9
The current A on the input side and the current A' on the output side are the sum of the anode current Ip value and the high voltage bleeder resistor 15. When this current, that is, the current A on the input side exceeds a predetermined constant value, an operating voltage signal B is output from the detection circuit 9, and the horizontal oscillation stop circuit 10 is activated. When the stop circuit 10 is activated, the oscillation function of the horizontal oscillation circuit 11 is stopped, the generation of high voltage is stopped, and the CRT 16 is prevented from being overloaded. In other words, the overcurrent detection circuit 9 and the horizontal oscillation stop circuit 10 constitute a protection circuit for the CRT 16. Note that when the current A exceeds a certain value, this means that the cathode of the CRT 16 is short-circuited and the automatic brightness control loop becomes open.

However, when the CRT 16 and the like operate under normal conditions, instantaneous discharge may occur within the CRT 16. At that moment, an excessive pulse of anode current A flows, activating the high-voltage stop circuit that serves as a protection circuit for the CRT 16. In other words, when a momentary discharge occurs inside the CRT16,
There was a drawback that the image displayed on this CRT16 suddenly disappeared.

The present invention solves the above-mentioned drawbacks, and an embodiment thereof will be described based on the circuit added to FIG. 4 is a capacitor such as an electrolytic capacitor, and this capacitor is connected to the power source _E2 . Reference numeral 5 denotes a resistor connected in series to the capacitor 4, and this resistor is connected to the connection point Q via the connection point P.
The connection between the capacitor 4 and the resistor 5 constitutes a detection circuit that instantaneously responds to changes in the anode current. 6 is a PNP type transistor whose base is connected to the connection point P, its emitter is connected between the capacitor 4 and the resistor 5, and its collector is grounded via the resistor 7. 8 is an NPN type transistor whose base is connected to the collector of the transistor 6 and whose emitter is connected to ground, and whose collector is connected to the horizontal oscillation stop circuit 10. These transistors 6 and 8 constitute the control circuit of the present invention.

Here, the function of the above configuration will be explained. During normal operation, capacitor 4 is open to direct current, so transistors 6, 8 are in an off state. Now, when a momentary discharge occurs,
An instantaneous negative pulse is generated at the connection point P. Therefore, the capacitor 4 becomes short-circuited, the emitter of the transistor 6 becomes equal to the DC power source _E2 , and a current flows through the resistor 5 to turn on the transistor 6. At the same time, the current flowing through resistor 7 turns on transistor 8. Thus, the collector of transistor 8 is close to zero potential. This drop near zero potential is sent to the horizontal oscillation stop circuit 10 as a voltage signal B' that cancels the voltage signal B that operates the horizontal oscillation stop circuit 10. As a result, the horizontal oscillation stop circuit 10 will not operate even if a momentary discharge occurs within the CRT 16. In other words, the horizontal oscillation circuit 11 continues normal oscillation operation when a momentary discharge occurs within the CRT 16.

The above operation will be further explained based on FIGS. 1, 2, and 3. A current A proportional to the anode current Ip flowing through the CRT 16 flows into the overcurrent detection circuit 9. When the discharge in CRT 16 causes current A to exceed a predetermined value determined by transistor 91 and resistor 92, transistor 91 is turned on and transistor 93 is turned on.
As a result, the voltage signal B for operating the horizontal oscillation stop circuit 10 is sent from the collector of this transistor 93 to the input side of the load resistor 101 of this stop circuit 10. At the same time, a negative pulse is generated at the connection point P due to discharge, so that the transistors 6 and 8 are turned on. As a result, the offset voltage signal B' of almost zero potential is sent to the output side of the load resistor 101 of the horizontal oscillation stop circuit 10, so the horizontal oscillation stop circuit 10 does not operate. In addition, 103 in FIG. 3 is a Zener diode for the reference voltage, and 102 is a transistor. When this transistor 102 is turned on and exceeds the reference voltage of the diode 103, the stop signal St
is sent to the horizontal oscillation circuit 11.

[Brief explanation of drawings]

FIG. 1 is a block circuit diagram showing an embodiment of the present invention, and FIGS. 2 and 3 are electronic circuit diagrams showing the essential parts of the same embodiment. 6, 8: control circuit, 9, 10, 11: high voltage stop circuit, 16: cathode ray tube.

Claims (1)

[Claims for Utility Model Registration] A television equipped with a high-voltage stop circuit that detects an overcurrent of the anode current of a cathode ray tube and uses the detected output to stop the generation of high voltage applied to the anode of the cathode ray tube. The receiver includes a detection circuit that responds only to an instantaneous change in anode current that occurs in the overcurrent detection section based on the internal discharge of the cathode ray tube, and a high-voltage stop operation that is performed at the moment of the internal discharge. and a control circuit for controlling the high-voltage stop circuit according to the output of the detection circuit so that the high-voltage stop circuit is prevented from malfunctioning.