DE1270088B - Vertical deflection circuit for televisions - Google Patents

Description

Vertical deflection circuit for televisions The invention relates to on a vertical deflection circuit for televisions, in which the linearization of the Sawtooth current in the transformer connected deflection coils from the output circuit the deflection amplifier to the input circuit, e.g. B. the charging capacitor of the control generator, a frequency-dependent negative feedback is provided. The invention aims at Circuits of this type stabilize the deflection amplitude against mains voltage fluctuations or the like.

To stabilize the deflection amplitude, it is known (German Auslegeschriften 1050 929 and 1166 819) to obtain a control DC voltage by rectifying an AC voltage taken from the output circuit of the deflection tube by means of a diode or a non-linear resistor and to use this at the control grid of the deflection tube to shift the operating point or for slope and gain control. The control voltage remains essentially unchanged. This regulation is also effective in the case of tube aging, in which case the operating point is shifted more towards the positive.

It is also known to stabilize the vertical deflection amplitude to keep the screen grid voltage of a deflection tube constant. Apart from this, that it is a matter of stabilizing an operating voltage here this solution requires additional power for stabilization.

It is also known (German Auslegeschrift 1176 185) to stabilize the supply voltage of the control generator with a VDR resistor. Finally, a stabilization circuit with rectification of flyback pulses has also been proposed, in which the rectifier circuit used to obtain a control voltage has such a time constant that the control voltage obtained contains an alternating voltage component which is used to influence the shape or amplitude of the control voltage. This proposed circuit works on the principle of the so-called tracking charging voltage.

The invention is based on the object of a vertical deflection circuit to create a stabilization of the deflection amplitude against mains voltage fluctuations is provided and in which self-excitation is largely avoided. The invention starts from a vertical deflection circuit for televisions with an improvement the stability between the output and input circuit of the deflection amplifier non-linear resistance.

The invention consists in that the only during the duration of the return pulses permeable nonlinear resistor with the parallel connection of a resistor and a capacitor of such a rating is connected in series that the capacitor a sawtooth voltage with a falling long edge arises, and that the sawtooth voltage via an integrating resistor-capacitor element in the negative feedback sense is coupled to the input circuit. The nonlinear resistance, in particular one VDR, is z. B. biased so that its operating point is in the positive range. The positive return voltages therefore open the VDR wide and charge the one in the shunt branch lying capacitor on. As soon as the return peak is over, the VDR blocks and the charged capacitor discharges through the shunt arm resistance after one e function. This means that the voltage at the shunt arm resistance, which is used for negative feedback, otherwise obtained through differentiation Has shape, but no longer contains a return voltage spike. This circuit has however, compared to the otherwise customary differentiator, the advantage that only the peak amplitude the return voltage has an influence, while all changes during the trace, which are given, for example, by the shape of the characteristic curve or similar influences, none Have more influence.

In the following the invention is based on several exemplary embodiments explained in more detail.

F i g. 1 shows a self-oscillating vertical deflection circuit, FIG. 2, 3, 4 further developments of this circuit. In Fig. 1 shows the vertical deflection circuit of a television receiver with two multivibrator tubes 1 and 2. In the anode circuit of the tube 1 serving as a deflection tube, an output transformer 3 is arranged, to whose secondary winding 4 the deflection coils 5 are connected. The tube 2 acts as a switch tube, which is fed to the grid via a capacitor 6 vertical sync pulses 7 which, for. The feedback path of the multivibrator circuit goes from a tap on the primary winding 8 of the output transformer 3 via a differentiating element 9, 10 and an integrating element 10, 11 to the control grid of the switch tube 2. The feedback path is like this dimensioned that the feedback pulse fed to the switch tube 2. receives the required shape and amplitude. The anode of the switch tube 2 is connected to the operating voltage via a resistor 13 and to a reference voltage via the charging capacitor 14, in the present case to the cathode circuit 15 of the deflection tube 1. The sawtooth voltage caused by the charging capacitor 14 through the switch tube is supplied via a coupling capacitor 16 to which the series circuit a capacitor 17 and a resistor 18 are connected in parallel to the control grid of the deflection tube 1. In order to generate a linear current in the deflection coils 4, the anode of the deflection tube 1 is fed back to the grid circle via a negative feedback path, a resistor 12 being inserted for tangent equalization.

In the circuit described so far, the negative feedback path is designed so that a non-linear resistor 20 is connected to the anode of the deflection tube 1, which via a resistor 21 and a capacitor 22 at a reference potential, for. B. mass, lies. The upper end of the circuit 21, 22 is connected via a capacitor 23 and a resistor 24 to the connection point of the coupling capacitor 16 "and the grid bleeder resistor 25 of the deflection tube 1. The non-linear resistor 20 has an operating point due to the effect of the positive operating voltage for the deflection tube 1 , which is well in the positive range. Therefore, the nonlinear resistance becomes even more permeable by the action of the positive return voltage peaks 26, while it is blocked by the trace part, the voltage at the anode of the deflection tube. This means that the capacitor 22 is charged and, as soon as the return pulse 26 is over, discharges according to an exponential function via the resistor 21. This results in a sawtooth curve 27 at the upper end of the circuit 21, 22, which via the capacitor 23 and the grid discharge resistor 25 into the input circuit This is where the resistance acts 24 and the charging capacitor 14 integrating this sawtooth voltage. The negative feedback voltage thus follows the amplitude of the return voltage peaks, while in the previous negative feedback circuits, the return pulse was suppressed by integration in the negative feedback path. In this way, the percentage mains voltage fluctuations are fed back with relatively larger absolute values.

F i g. FIG. 2 shows a modification of the circuit according to FIG. 1, in which the same circuit elements as in FIG. 1 are provided with the same reference numerals. To avoid unnecessary repetitions, only the essential differences are shown here. The non-linear resistor 20 is shown in FIG. 2 connected in series with a capacitor 27 between the anode of the deflection amplifier tube 1 and ground. It has the function of return damping. The capacitor 27 is dimensioned so large that a substantially linear sawtooth voltage drops across it. When the mains voltage changes, the amplitude of the sawtooth voltage on the capacitor 27 also changes approximately proportionally to the flyback voltage. The series connection of an adjustable resistor 28 and the parallel connection of a resistor 29 and the series connection of a capacitor 30 and a further resistor 31 are parallel to the non-linear resistor 20 in Fig. 1, forwarded. In the circuit modified so far, the linear sawtooth voltage 32 is derived from the capacitor 27 and superimposed on the sawtooth voltage 33 obtained by the differentiating element 30, 31, 28. Compared to the circuit according to FIG. 1, this circuit has the advantage of better geometry equalization, ie better linearity.

The in the F i g. 1 and 2 can also be used in vertical deflection circuits with transistors. Such an embodiment is shown in FIG. 3 shown. One of the switch tube 2 in FIG. 1 corresponding switch 35 is connected to an operating voltage via a resistor 36. When the switch 35 is open, a charging capacitor 37 is charged via the resistor 36 and periodically discharged via the closed switch 35. The voltage generated at the capacitor 37 is connected via a coupling capacitor 23 to the base of a driver transistor 38, the output resistor 39 of which is connected to the base of the output transistor 40. In the output circuit of the transistor 40 is the primary winding 8 of the output transformer 3, to whose secondary winding 4 the deflection coils 5 are connected. A further winding 41 is coupled to the primary winding 8 of the transformer 3 and is connected in series with a non-linear resistor 42 in parallel with the coupling capacitor 23 of the driver transistor 38 . The parallel connection of the capacitor 43 and an adjustable resistor 44 is parallel to the series connection 41, 42. One end point of the parallel connection described so far is to the coupling capacitor 23, the other end point via the series connection of an adjustable resistor 45 and a capacitor 46 to the base of the transistor 38 or the base resistor 47 is connected.

F i g. 4 shows a simplified circuit according to FIG. 1, in which the circuit 21, 22 is switched on at the same time in series in the base of the charging capacitor 14 . It is thereby achieved that the charging capacitor 14 is superimposed on an anti-phase linear sawtooth voltage which changes proportionally to the flyback voltage. The circuit corresponds to the function of the circuit F i g. 2.

Claims (6)

Claims: 1. Vertical deflection circuit for television sets with a non-linear resistor switched on to improve the stability between the output and input circuit of the deflection amplifier, characterized in that the non-linear resistor (20), which is permeable only during the duration of the return pulses, with the parallel connection of a resistor (21) and a capacitor (22) is connected in series so that the capacitor (22) has a sawtooth voltage with a falling long edge, and that the sawtooth voltage is coupled to the input circuit via an integrating resistor-capacitor element (24, 14) in a negative feedback sense will. 2. vertical deflection circuit according to claim 1, characterized in that that parallel to the series connection of the non-linear resistor (20) and a part of the resistor (21) located in the shunt branch, a further resistor (12) is connected is. 3. vertical deflection circuit according to claim 1 or 2, characterized in that that the non-linear resistor and the capacitor or resistor in series are connected between the anode of the deflection amplifier and ground. 4. Vertical deflection circuit according to one of the preceding claims, characterized in that the parallel connection of the resistor and the capacitor is connected in series with the charging capacitor. 5. vertical deflection circuit according to one of claims 1 to 4, characterized in that that when using transistors with driver stage and output stage in the control circuit a secondary winding of the output transformer is connected to the driver stage, those in series with the non-linear resistor in parallel with a capacitor resistor circuit is switched. 6. Vertical deflection circuit according to claim 1, characterized in that the parallel circuit (41, 42, 43, 44) is parallel to the coupling capacitor (23). Considered publications: Deutsche Auslegeschriften Nr. 1050 929, 1166819.