DE2324045A1 - REGULATED HIGH VOLTAGE DEVICE FOR CATHODE BEAM TUBES - Google Patents

Description

Regulated high voltage device for cathode ray tubes The invention refers to a control circuit for high voltage devices to supply Cathode ray tubes and especially television pick-up tubes that use the electron beam distracted and groped during a certain interval, but during of another interval is fed back and blanked. To such voltage devices becomes the requirement of very extensive constancy and low inertia in control processes posed.

In addition, particularly in the case of very compactly constructed high quality cameras The following requirements are placed on the high-voltage device for It-Applied TV: 1. Avoidance of any image distortion.

2. Avoidance of any noise.

3. Good electrical efficiency.

4. Avoidance of large-volume components.

.5. Possibility to dispense with any comparison process by using components that are easy to control in terms of their tolerance.

6. Economy by using commercially available, relatively cheaper ones Circuit elements.

7. Protection against overload and short circuit.

8. Independence from the mode of operation and setting status of others 3 circuit functions.

In the previously known high voltage generators with stabilization the requirements are only partially met, although a large number. of circuit principles is known. One for a long time with television display tubes Circuit principle used for high voltage stabilization according to the parallel regulator method provides e.g. a compensation triode which out of phase with the electron beam of the cathode ray tube is controlled, so that the high voltage device is loaded by a constant current. A disadvantage of this circuit is-in the power to be constantly applied for the compensation triode and thus in the Failure to meet the requirement for good electrical efficiency.

Furthermore, one has in circuits in which the high voltage from the Line deflection device is removed, stabilization by regulating the power supply unit provided, which feeds the deflection device and the high voltage generator. here However, due to the coupling of high voltage and deflection, it is only to a limited extent Area ensures stability of the high voltage or the image section. Such a control of the power supply unit can be achieved, for example, by phase control performed with a thyristor or a triac by taking off the mains frequency Impulse was formed, the width of which is made dependent on the magnitude of the high voltage became. For this purpose, a resistor was placed at the base of the high-voltage transformer provided and the voltage occurring there after further amplification of a comparison circuit supplied, with the help of which the width of the said pulses was then influenced. But there is only a fraction of the high voltage at the base resistance and a corresponding one If there is a small fraction of the alternating voltage, this regulation is not very sensitive.

Another system is described in German Auslegeschrift 20 59 133 and the laid-open specification 20 24 372, in which a high-frequency alternating voltage is coupled into the rectifier circuit of the high-voltage generator, the amplitude of which depends on deviations in the high voltage.

In these cases, however, picture disturbance is possible because the pulses generated during the trace period as parasitic Disruptions occur in the various signal circuits and the quality of the television picture influence, for example by the occurrence of a so-called mains hum.

The present invention is therefore about the task specify a stabilized high-voltage circuit that has the disadvantages described known circuits and also avoids the requirements specified at the beginning with regard to the circuit properties is able to meet. The invention refers to a method for generating the ffoch tension by chopping a specified DC voltage and converting the resulting voltage pulses into a high voltage with the help of a multiplication cascade and without use a converter transformer.

A converter transformer is a relatively expensive, non-standardized one and thus not commercially available component with a relatively large space requirement, its overall height In very compact TV cameras, this leads to considerable accommodation difficulties and which often requires special measures to prevent the occurrence of interfering noise to avoid.

The circuit for stabilizing the high voltage for a cathode ray tube, which are equipped with a high-voltage generator powered by chopped direct current is, is characterized according to the invention in that the switch-on time of the circuit breaker the current source is determined by the width of a pulse, its phase of action only lies within the blanking time of the deflected cathode ray, and that the Width of the pulse depends on a control voltage, which is in a comparison circuit by comparing a partial voltage of the high voltage and a reference voltage is won.

The chopping pulse of adjustable width is advantageous Prepared comparison circuit, which on the one hand the control DC voltage and on the other hand, a sawtooth pulse is supplied, which only occurs during the retrace of the electron beam and synchronized with the return pulse of the deflection system is. Such a comparison circuit can e.g.

be a differential circuit with two transistors, one input of which the sawtooth voltage and the other the control voltage is supplied with the Reference voltage can also be used as a short-circuit fuse, which is in operation occurs when the voltage change far exceeds the control range. In this Case, the comparison voltage is controlled so that no pulses are sent to the circuit breaker and this is shut down. Finally you can move on to further To increase operational safety, set up a start-up circuit on the reference voltage, which simulates a control voltage on the comparison circuit for as long as it has been no high voltage has occurred at the output of the high voltage generator.

These and other details are given below with reference to the figures 1 and 2 explain in more detail of which FIG. 1 is a block diagram, FIG. 2 is a complete one Circuit diagram for generating a regulated high voltage for cathode ray tubes reproduces from a mains transformer.

In Fig. 1, block A represents a network transformer, block B shows a rectifier circuit, at the output of which an unstabilized DC voltage arises, which must be sufficient to generate the high-voltage line. These DC voltage is fed to a circuit breaker C, which is from Pulses of variable width is controlled. The greatest breadth of the impulses should approximately equal to the width of the return pulse of the cathode ray array or the Be the width of the blanking pulse. The one at the output of the circuit breaker The voltage can now be adjusted to the required level with a known type of rectifier cascade High voltage are implemented. It therefore appears at output E across the capacitor c the desired high voltage. So now one of load fluctuations or mains voltage disturbances independent high voltage is obtained, a control circuit is provided whose Design and function according to the invention is described below: The output E of the high voltage source is connected to the input via a high resistance F the comparison circuit J connected, in which the control voltage is processed. The comparison circuit J works in the manner of a cut-off stage, which is on a first input a sawtooth voltage and another input a direct voltage is fed. Then occurs at its output connected to the circuit breaker C. a pulse only in the time segments in which the sawtooth amplitude is the control voltage exceeds.

The sawtooth voltage fed to one input of the comparison circuit has according to the invention only in the retrace or blanking time of the electron beam a rising edge, but only one below the minimum value during the trailing edge the control voltage level. This sawtooth is derived from the synchronization pulse generated for the horizontal deflection of the cathode ray deflector. The sawtooth generator itself is denoted by K.

The overall circuit diagram shown in FIG. 2 points on the left a mains transformer A to 1 whose secondary-side voltage to the rectifier 3 is fed. The generated voltage is input voltage (basic voltage) for the high voltage generator. It is summarized in the unit C by the Circuit breaker chopped with the complementary transistors 2a and 2b, the chopping pulses are fed from the amplifier 12 to the base electrodes of the two transistors. The chopped DC power is drawn between the two transistors and to the high-voltage cascade D with the capacitors 4c and the rectifiers 4d, the operating high voltage for feeding the anode of cathode ray tubes is then available at terminal E.

So that the operating voltage at terminal E from load fluctuations is independent and free of ripple voltages are used to control the circuit breaker C square pulses of the line frequency used, the width of which corresponds to the Load of the high voltage device is controlled. For this purpose, the high voltage is used. superimposed disturbance separated and the one consisting of the transistors 8 and 11 Differential amplifier supplied.

At the base of a transistor 11 are sawtooth pulses whose sloping edge is only present during the ramp-down time; during the run-out time there is only a constant reference level. This sawtooth pulse is created by the charging of the capacitor 20 in the circuit unit K and the then occurring Discharge through transistor 101 which is controlled by the line sync pulses that are applied to terminal 21. On the other side of the differential amplifier is at the base of the transistor 8, the control voltage derived from the high voltage created. For this purpose there is a resistor combination between the high voltage source and earth RIl R2, and a constant current generator placed with the transistor 5, the base of which via the transistor unit j connected as a diode to the constant voltage source, about a Zener diode 13 is connected. The transistor 7 serves to compensate of temperature changes acting on the transistor 5. Through this interconnection of the constant current generator 5 with the high voltage source becomes the high voltage at the collector of transistor 5 by a constant amount degraded, which can be equal to the prescribed Roch voltage. It then remains on the collector of the transistor 5 only the fluctuations in the high voltage due to the change in Load or other influences. The control voltage at the base of the transistor transistor 8 determines the cut-off level of the sawtooth pulse at the base of the transistor 11, so that at the collector of transistor 8, an approximately triangular pulse of one Duration occurs which is generally smaller than the width of the sawtooth pulse 11 is. In the amplifier unit 12 the phase is rotated and the pulse steepened further, so that it has a shape as shown next to the block unit C. To the right next to the transistor 8 an arrow is drawn, which indicates the cut-off level, which is generated on the sawtooth pulse 11 drawn to the left of the transistor. The circuit also contains two further details that are necessary for starting the control circuit and serve to protect against high voltage short circuits. In the circuit unit L is a transistor 6 with its emitter-collector path between the control voltage line and the operating voltage source is applied. The base of this transistor is over a Time constant element from resistor R3 and capacitor 16 on the operating voltage line connected, and the resistor R3 is bridged by a diode 14. These The start-up circuit is used to simulate a high voltage when switched on and therefore only works temporarily. When switched on, the base of the Transistor 6 quickly via the capacitor 16 an opening voltage, which, however, with of the time constant R7 C16 decays. The diode 14 comes into operation when switching off, by preparing the capacitor 16 for switching on again as quickly as possible.

The switching elements in the block unit serve to protect against short circuits M. It contains a diode 15, which supplies the transistor 8 with a reverse voltage as soon as by shorting the voltage at the base of transistor 8 below the reference voltage has sunk. As a result of this blocking, no control pulse can be used at the Collector of transistor 8 can be applied more, so that the energy supply between the rectifier 3 and the cascade D is interrupted. On the other hand, if the control voltage higher than the operating voltage of the transistors, e.g. 12 volts, occurs the diode 22 in parallel next to the switch-on transistor 6 in function and limits the at the base of the transistor 8 effective control voltage.

In detail, the requirements specified at the outset are therefore implemented the circuit according to the invention fulfills the following: 1. Avoidance of any image disturbance even in the case of interference voltages present on the mains voltage due to the filter and storage effect the rectifier circuit B, through the synchronization of the switching pulses generated with the line frequency via terminal 21 (independence from the mains frequency) and through the pulse width control within the blanking time, creating switching edges can be avoided during the visible image and enables rapid regulation will.

2. The risk of noise is avoided that according to the invention no converter transformer is used.

3. Good electrical efficiency is achieved in that as the input voltage for the high-voltage generator, the unregulated one obtained in block B. DC voltage is used and that the high voltage regulation across the width the switching impulse takes place.

4. The saving of a converter transformer enables compact built cameras have a very flat structure of the circuit.

5. As the level of the regulated output voltage is very largely only through the reference voltage (Zener diode 13), the current source G (R4) and the resistor F (R1 and R) is determined, 1 2 can be achieved by tolerating these components accordingly easily one low specimen variance of the regulated high voltage can be achieved, which makes it possible to dispense with any adjustment process.

6. Profitability becomes through the use of commercially available, relative cheaper components and bypassing a relatively expensive, laboriously wound Converter transformer reached.

7. Reliable protection against overload and short circuit is provided by the Diode 15 according to the invention achieved.

8. The regulated high voltage is independent of the mode of operation and Setting status of the horizontal deflection circuit and also cannot via the input terminal 21 can be influenced.

Claims (5)

Claims Circuit for stabilizing the high voltage for cathode ray tubes and the like. Which by a voltage converter from a chopped direct current is obtained, characterized in that the switch-on time of the current source (B), which feeds the voltage transformer, is determined by the width of a pulse, whose phase of action lies within the blanking time of the deflected cathode ray, and that the width of the pulse is dependent on a control voltage that is in a Comparison circuit (J) by comparing between a fraction of the high voltage and a voltage standard is obtained. 2. Circuit according to claim 1, characterized in that the switching pulse by cutting off a rising pulse and return pulses during the blanking time synchronized sawtooth voltage is formed by means of the control voltage. 3. A circuit according to claim 1 or 2, characterized in that the Comparison circuit made up of a high-resistance resistor and a constant current source exists whose current is stabilized by means of a reference voltage source, and that the deviation of the high voltage from a predetermined value at the connection point between the resistor and the constant current source is taken. 4. A circuit according to claim 1 to 3, characterized in that the Control voltage at the emitter-collector path of a transistor (6> lies 1 of its Base is placed on opening voltage via a time constant member, such that with delayed Switching on the high voltage through a backup power the transistor - (8) flows and the switching pulse directly in the comparison circuit (J) triggers after switching on the device. 5. Circuit according to claim 1 to 4, characterized in that the Generation of switching pulses in the comparison circuit (J) is interrupted when the voltage at the comparison circuit due to an overload of the high voltage (J) drops below the reference voltage (diode 13) which determines the constant current by the emitters of (J) are kept at the reference voltage via the diode (M).