DE2326399C3 - Circuit for stabilizing the operating voltage for the line output transistor in a television receiver - Google Patents

Description

The main patent relates to a circuit for stabilizing the operating voltage for the line output transistor in a television receiver with a control voltage derived from the change in operating voltage, wherein a first electrode of the transistor with the non-stabilized operating voltage and a second Electrode of the transistor is connected to earth.

It is known to control a further transistor with the control voltage, which in the way of the BetriebsstrniTiLv -u the Vc-bm ^ -hrr cherishes. This transistor must have a relatively high dielectric strength.

The invention according to the main patent is based on the object of simplifying this circuit in such a way that that the second transistor can have a lower dielectric strength.

This object is achieved by the invention according to the main patent in that the second electrode, especially the emitter, the output stage transistor

ίο over one influenced by the control voltage Impedance is connected to earth If a transistor is used for the impedance, then this can have a low dielectric strength.

Said second transistor reduces the operating voltage effective at the line output transistor. This is desirable because in a television receiver without a mains transformer, the rectified Mains voltage is too high for the line output transistor anyway. As the second, regulated transistor only If a low voltage is to be absorbed, the rectified mains voltage is often still there undesirably high, so that the filter elements following the power rectifier have a relatively high resistance. power consuming resistors must be provided.

The present invention is based on the object with the circuit according to the main patent to feed another consumer in addition, in such a way that the rectified mains voltage is better is exploited and does not have to be converted into heat uselessly.

The invention consists in that between the end of the impedance facing away from the output stage transistor and earth the operating voltage terminals of the vertical deflection stage are connected, which in the output stage with two complementary, push-pull and AB mode transistors.

According to a preferred embodiment of the invention, that of the impedance, that is to say the regulated one

• Ό transistor, remote operating voltage terminal of the Vertical deflection output stage not directly to earth, but to earth via a voltage stabilization element connected, from which an operating voltage for another consumer, z. B. the working in B operation Audio audio output stage, has been removed. This circuit is the subject of the earlier application P 23 13 708.8. at In such a circuit there are four between the actual operating voltage terminal and earth Assemblies connected in series, namely the line output transistor, the second transistor used for regulation, the vertical deflection output stage and the stabilization element to generate an operating voltage for the audio audio output stage. The high rectified Mains voltage is then optimally used and does not need to be partially converted into heat. One had to assume first that with such a series connection of consumers different Voltage curves, namely line frequency, image frequency and audio frequency, of which the

^{b (l the} power consumption of the audio output stage fluctuates considerably depending on the level, a disturbance occurs between the individual stages. It has been shown, however, that, surprisingly, no such mutual influence can be ascertained

^{ΙιΓ> is when, according to the} invention, the AB mode is selected for the vertical deflection output stage. It is also possible to provide a B operation instead of the AB operation and use the operating voltage terminals of the vertical

to bridge deflection output stage with a voltage stabilization element.

The invention is explained with reference to the drawing. In it shows

F i g. 1 shows an embodiment of the invention, FIG. 2.3 curves to explain the mode of operation.

F i g. 1 initially shows the circuit according to the main application with terminals 1 carrying the mains voltage, a mains rectifier 2 which supplies a high operating voltage + U _x of + 200V for the flyback stage at a clamp 3 , a line output transistor 9, a transformer 11 fed by the control voltage 10, a flyback capacitor 12, a coupling capacitor 13, which is also used for tangent equalization, and deflection coils 14. The deflection coils 14 cause the line deflection in the picture tube 15 to which the rectifier 8 obtained High voltage is applied via a line 16

The circuit according to the invention according to the parent application contains parts 17-23. As a result, a manipulated variable U _{s is} generated on line 18, which is a measure of the actual operating voltage across the line output stage, that is to say for the voltage between terminals 3, 27. In accordance with this manipulated variable, the conductivity of transistor 17 is controlled so that the voltage between terminals 2, 27 remains constant. A resistor 50 takes over part of the current λ and relieves the transistor 17.

The Zener diode 28, the resistor 31 and the capacitor 32 form a voltage stabilization circuit which generates an operating voltage + Ui for a Ton-NF output stage 34 at a terminal 37. This>■> feeds a loudspeaker 35 and is supplied with an LF voltage from a terminal 36. The audio output stage works in B mode, so that the current consumption depends on the level. This circuit works according to the earlier application ίο P 23 13 708.8.

According to the invention, the vertical deflection stage 38 with its operating voltage terminals 39, 40 is connected between the lower end of the transistor 17 and the Zener diode 28. Between the terminals 39, 40 there is the operating voltage t / ₄ of about 35 V for the entire deflection stage 38. This feeds the vertical deflection coils 42 for the picture tube J5 via a coupling capacitor 41 are controlled by a driver stage 45. The driver stage 45 is controlled by a generator 46 which is synchronized by synchronizing pulses 47. The terminals 39, 40 are bridged by a capacitor 48 which practically represents a short circuit for the line frequency. ίί

The following is the advantageous interaction between the terminal 3 and earth a total of 4 levels, namely 9,17,38,28 explained.

Because stage 38 takes over the operating voltage U * , part of the voltage + Uy at terminal 3, which is too high for transistor 9 anyway, is consumed in the desired manner, so that this part of U \ does not pass through Resistors need to be converted into heat. The voltage ■ + U- therefore does not need to be further reduced. ι ·.

A disturbing influence of the stage 38 on the line output stage transistor 9 does not occur because the Rcgelschalttir.p after the main patent with the Control transistor 17 controls the operating voltage across the line output stage, i.e. between terminals 3, 27 stabilized, regardless of how they change the ratios below the transistor 17.

If the control of the stage 34 changes, its current consumption changes considerably, so that the direct voltage between the terminals 39, 40 shifts and the effect of the pulses 47 on the circuit 38 could be impaired. It has been shown, however, that the associated change in voltage + U ₃ at terminal 37 is small compared to the amplitude of synchronizing pulses 47. The change in load at point 37 therefore also has no disruptive influence on stage 38. Should amplitude fluctuations or synchronization disturbances also occur Complete overriding of stage 34 can be avoided, an additional current U can be fed into the Zener diode 28 via a resistor 50 from a current source with a voltage above ίΛ, so that this diode always remains live, even with the smallest beam current and thus the lowest Z ₁ . The current U can be supplied by an additional winding of the transformer 6. Mains voltage fluctuations do not result in any change in current through the circuit 38, since they are fully regulated by the transistor 19.

If the beam current of the picture tube 15 changes, the operating current λ impressed on the stage 38 changes according to FIG. 2. The AB operation now has the advantageous effect that, with the change in the current shown, the operating voltage U * effective across the stage 38 changes in a much smaller percentage, as shown in FIG. 2 shows. This slight change in ίΛ in the event of fluctuations in brightness also has an advantageous effect on the overall effect of the circuit; ie there is practically no noticeable vertical amplitude fluctuation when the beam current changes.

3 shows the current curve in the two transistors 43, 44 for AB operation. The stream / 3 im Transistor 44 is zero during the first half of the trace, that is to say during the upper half of the image, and then wins linear. The current I2 in transistor 43 falls linearly during the first half of the trace, but is during the second half of the trace is not zero, but assumes a constant value. This so-called AB operation of the Transistors 43, 44 are decisive for the advantageous effect of the overall circuit.

One would first have to assume that stage 38, which processes a 50 Hz signal with relatively high power, has a disruptive influence on stage 34 in the form of an audible 50 Hz hum. However, this malfunction does not occur either. This is due to the fact that on the one hand the current i _x flowing into the stage 38 is kept constant by the control circuit with transistor 17 and is therefore not superimposed by a 50 Hz component, and on the other hand the voltage + Ui is stabilized by the Zener diode 28 is.

A disruptive coupling of the line frequency from the line output stage into the vertical output stage 38 is avoided by the capacitor 48, which practically represents a short circuit for the line frequency. In addition, the capacitor 49 conducts the line-frequency components of the current to the entire line output stage The series connection of transistor 17. Circuit 38 and circuit 34 over to ground.

Parallel to the terminals 39, 40 there can also be one Voltage stabilization element connected, the

If the currents / 2, / 3 are interrupted, the voltage Ut is limited and the capacitor 48 is protected.

With a mains voltage of HOV, the voltage + U \ of around 200 V required for the entire circuit can be obtained by a voltage doubler circuit in the power supply unit.

1 sheet of drawings

Claims (7)

Patent claims: 1. Circuit for stabilizing the operating voltage for the line output transistor in one Television receiver with a control voltage derived from the change in operating voltage, wherein a first electrode of the transistor with the non-stabilized operating voltage and a second Electrode of the transistor via an impedance influenced by the control voltage with earth is connected according to patent P 22 58 57C.2, thereby characterized in that between the end of the transistor (9) facing away from the output stage Impedance (17) and earth connected to the operating voltage terminals (39, 40) of the vertical deflection stage (38) are that in the output stage with two complementary, push-pull and AB mode working Transistors (43,44) is populated 2. A circuit according to claim 1, characterized in that instead of the AB operation, a B operation is used and a voltage stabilizing element is connected in parallel to the operating voltage terminals (39, 40) of the vertical deflection output stage (38). 3. A circuit according to claim 1, characterized in that the impedance (17) facing away Operating voltage terminal (40) of the vertical deflection output stage (38) with earth via a voltage stabilization element (28) is connected, from which an operating voltage (+ ίΛ) for another consumer (34) is removed. 4. A circuit according to claim 3, characterized in that the further consumer is the audio audio output stage (34) is. 5. A circuit according to claim 1, characterized in that in parallel with the operating voltage terminals (39, 40) of the vertical deflection output stage (38), a capacitor (48) is connected for Line frequency is practically a short circuit. 6. A circuit according to claim 1, characterized in that parallel to the operating voltage terminals (39, 40) of the vertical deflection stage (38), a voltage stabilizing element is connected such that it limits the voltage (LU) above it in the event of a power interruption between the operating voltage terminals. 7. A circuit according to claim 3, characterized in that in order to avoid amplitude fluctuations or synchronization disturbances at the vertical deflection stage (38) when the further consumer (34) is overridden in the voltage stabilization element (28) from a source whose voltage is greater than that on This element, an additional current (U) is fed.