DE2546226C3 - Circuit arrangement for keeping the picture size of a television receiver constant with a horizontal deflection circuit based on the pumping principle - Google Patents

Description

The invention relates to a circuit arrangement according to the preamble of claim 1 and is a Addition to DE-PS 23 57 705.1 In the main patent. Is the so-called pump circuit described with a current pulse stabilization. Further embodiments of the Pump circuit are in the journal "Siemens-Components-Report" 12 (1974), Heil3, pages 61 to 64, and issue 4, Pages 96 to 98 included. The current pulse stabilization protected in the main patent requires only a few additional components. It ensures that the energy feed is independent of network fluctuations is made by stabilizing the amplitude of the pump pulses by a Zener diode. The current pulse stabilized Pump circuit supplies a substantially constant load to the secondary consumers Current. This ensures that the horizontal deflection and high voltage compensate each other in such a way that that the image width remains essentially constant. However, the Charging capacitor from which the other functional groups of the television set are supplied with electrical energy are also supplied with approximately constant current. While some functional groups always have a constant If the current decreases, the currents of other functional groups change in an uncontrollable manner. These are above all the power requirement fluctuations of the Toin amplifier between about 0.5 and 5 W as well the power fluctuations of the vertical deflection circuit, which the voltage source periodically with 50 Hz Load the basic frequency.

This fluctuation in the power consumption can be caused by the circuit arrangement specified in the main patent not regulated so far that it no longer has any influence on the image size. Of the The present invention is therefore based on the object of the circuit arrangement of the main patent improve / u in such a way that the image size of the current pulse stabilized pump circuit are kept constant can.

This object is achieved by the characterizing features of claim 1. By using a voltage stabilization circuit that works on the principle of the parallel regulator and not the series regulator, the current drawn from the charging capacitor is kept essentially constant, so that the influence of power fluctuations on the the stabilized voltage connected consumer is rendered harmless to the image constancy. The ohmic resistance between the charging capacitor and the voltage stabilization circuit increases the internal resistance of the stabilized voltage source. Without this resistance, this clamping source would have an internal resistance of practically zero. The charging capacitor also serves as a voltage source for the actual Horizonialablenkschaluing and must therefore have a finite internal resistance, so that this voltage yields with a large image current. This operating voltage Un of the horizontal deflection circuit at the charging capacitor should go along with the electron beam current load so that in the event of high voltage fluctuations AUii caused by the internal resistance

stand of the high voltage source are conditional, the following Condition is met:

U ₁ ,

The ohmic resistance at the charging capacitor is set in such a way that the width of the image changes from the beam sirom is as independent as possible.

In order for the image height to remain stable, the in Operating voltage for the vertical deflection formwork have a certain internal resistance, which causes the operating voltage for the vertical deflection under loads also gives way. For this purpose, the low resistance between is the charging capacitor and the voltage stabilization circuit designed as a voltage divider. The operating voltage for the Vertical pivot circuit removed.

Further advantageous configurations of the invention 2 » and the structure of the voltage stabilization circuit according to the invention as a parallel regulator, in the form of an exemplary embodiment based on the drawing, j explained.

1 with a flyback transformer is designated, which carries a winding 2 on one side, through which current pulses are fed with the aid of a pump transistor 3 during the flyback of the electron beam. A line end transistor is denoted by 4, which is controlled at its base via an input 5 by horizontal pulses and which is part of a so-called saving diode circuit. In this saving diode circuit, the collector-emitter path of the row transistor 4, a diode 6 - the so-called saving diode -, a capacitor 7, the series connection of a capacitor 8 for the so-called tangent correction with a coil 9 for linearity control and with two parallel-connected horizontal deflection coils 10 and 11 and the series connection of a winding 12 of the flyback transformer 1 with a charging capacitor 13. The connection point of the winding 12 with the charging capacitor 13 is denoted by 14 and carries an operating voltage Un. Another winding 15 of the Zcilentransformalors 1 leads via a diode 16 to a terminal 17 for a high voltage U- This -r> terminal 17 is used for the picture tube as a high voltage source; for later consideration, an ohmic resistor 18 is shown in dashed lines and a capacitor 19 is shown in series with it. The ohmic resistance 18 represents the internal resistance rudder -) <> high voltage source and the capacitor 19 represents the picture tube capacitance C «.

From punk «. 14 with the operating voltage Un , the series connection of two ohmic resistors 20 and 21 leads to a terminal 22 at which a stabilized r> DC voltage of, for example, + 22V is available. A capacitor 23, the series connection of a Zener diode 24 with an ohmic resistor 25 and the series connection of the emitter-collector path of a transistor 31 with an ohmic resistor 26 lead from terminal 22 to the reference potential Ohmic resistor 25 leads via an ohmic resistor 27 to the base of a transistor 28. The transistors 31 and 28 are complementary to one another, the transistor 31 being of the pnp type and the transistor 28 of the npn type in this embodiment. The emitter of transistor 28 is at reference potential; the collector leads via an ohmic resistor 29 to the base of the transistor 31. The connection point of the two ohmic resistors 20 and 21 leads to a terminal 30 at which a supply voltage for a vertical deflection circuit is taken.

The elements 23 to 31 represent the voltage stabilization circuit used according to the invention, the Zener diode 24 serving as a reference element. The capacitor 23 with a large capacity of 470 μΡ, for example, also smooths the stabilized voltage picked up at the terminal 22. The operation of the voltage stabilization circuit is based on the fact that it absorbs excess power and thus keeps the voltage at terminal 22 constant. As a result, fluctuations in the power of the consumers connected to the terminal 22 can no longer affect the level of the voltage. This prevents fluctuations in the operating voltage Ue across the charging capacitor 13 for the line deflection circuit, so that they cannot have a disruptive influence on the image size.

Even if with this measure the voltage source 22 has an internal resistance of practically zero for the connected consumers. so this must not apply to the horizontal deflection and the vertical deflection. The operating voltage sources for these two deflections should go along "softly" according to the above formula, so that the image width and image height remain stable in the event of fluctuations in the high voltage AUu. The two ohmic resistors 20 and 21 fulfill this purpose, with the value of the ohmic resistance 20 being the internal resistance of the operating voltage source Un for the horizontal deflection and the resistance value of the ohmic resistance 21 being the internal resistance! for the operating voltage source 30 can be set for the vertical deflection.

To avoid transient processes, it is advantageous to choose the time constant of the two ohmic resistors 20 and 21 and of the charging capacitor 13 so that it is the same as the time constant of the internal resistance rudder high-voltage source 17 and the picture tube capacity Cn. which are represented by ücn ohmic resistance 18 and by the capacitor 19. It should then gellem (/ ?: "+ R ₂₁ ) · Cu = Kn-Ch.

For this purpose I sheet drawings

Claims (3)

Claims; 1. Circuit arrangement for keeping the image size of a television receiver constant with a horizontal deflection circuit which contains a saving diode circuit, a flyback transformer and a pump transistor, the high voltage for the picture tube and operating voltages for the television receiver being obtained via corresponding windings of the flywheel transformer, the pump transistor as a switch with its switching path in series between a working winding of the flyback transformer and a DC voltage source with a direct voltage obtained directly from the AC mains voltage and thereby delivers horizontal-frequency feed pulses into the horizontal deflection circuit and the pump transistor via a control winding of the flyback transformer from horizontal-frequency Im -> o pulsing is controlled, the emitter of the pump transistor via an ohmic resistor with the first connection and the base via the series connection of an adjustable ohmic resistor s and a fixed ohmic resistance 2 ° ϊ level is connected to the second connection of the control winding, furthermore between the first connection and the Vei connection point of the adjustable with the fixed ohmic resistance, a Z-diode is, furthermore, the Zener voltage jo tion of the Zener diode has a value of 50 to 90% of the amplitude of the maximum voltage induced in the control winding and the control winding is so loosely coupled to the working winding that the induced voltage has an η almost sinusoidal curve m ί flat edges takes or the induced voltage is deformed in a sawtooth or trapezoidal shape by a network, characterized according to patent 23 57 705.1, characterized in that the deflection circuit contains a charging capacitor (13) which serves as an energy source for other consumers that is parallel to the charging capacitor (13) a voltage stabilization circuit is connected, which works on the parallel regulator principle, and that between the Ladenko ndensator (13) and the voltage stabilization circuit an ohmic resistor (20) is connected. 2. Circuit arrangement according to claim!, Characterized characterized in that the between charging capacitor (13) and voltage stabilization circuit schal- w tete ohmic resistor (20) constructed as a voltage divider from two ohmic resistors (20,21) and that the operating voltage is at the connection point of the two ohmic resistors (20, 21) for a vertical deflection circuit -, -> is taken. 3. Circuit arrangement according to claim I or 2, characterized in that between a terminal (22) for the stabilized voltage and the reference potential the series connection of a w) Zener diode (24) with an ohmic resistor (25) and the series connection of the emitter-collector path a first transistor (31) with an ohmic resistor (26) lie that the Zener diode (24) via an ohmic resistor (27) to the base h-> of a second transistor that is complementary to the first (28) leads that the emitter of the / wide transistor (28) is at reference potential and that the collector is connected to the base of the first transistor (31) via an ohmic resistor (29) is