CS195992B1 - Connection of the starting circuit of the spacing scanning of the semi-conductor television receiver - Google Patents

Description

(54) Connection of the semiconductor television line decay generator starter circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a starter circuit generator for a semiconductor television receiver.

In modern television sets, low-voltage circuits are supplied from line decomposition, which is supplied from a mains power source, ie low-voltage sources start to supply power only after the line decomposition is started. This creates a problem for feeding the line scan driver, which must be in operation when the line scan starts. A low supply voltage is used for the driver circuits due to the transistors or integrated circuits used. In normal operation, it is advantageous for the exciter to be supplied from a line decomposition source with respect to higher stability and less ripple. Therefore, a special source is often used for start-up, which is disconnected after the start of decomposition or its influence is reduced. Common solutions of starter circuits are i

(a) a mains transformer with a rectifier which gives a lower voltage than in normal operation;

b) power supply with limited resistance directly from the mains rectifier,

c) power supply from circuits utilizing the charging current of the power supply smoothing capacitors for line decomposition.

In the solution according to a) it is advantageous that the supply voltage can be used also for other circuits, but its disadvantage is the relatively high laboriousness of the wound part and the associated costs,

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195 992 furthermore a narrow transformer tolerance and a small reserve for fluctuations in force voltage.

The solution according to b) is advantageous in that it is cheap in terms of cost. A significant disadvantage, however, is the relatively large energy loss, which in the case of commonly used circuits exceeds 10 W.

The advantage of the solution according to c) is relatively low material costs. On the other hand, a considerable disadvantage of this solution is the condition of very narrow tolerances of the components used in order to ensure reliable decomposition operation. Another disadvantage is the possibility of transferring the bromine voltage from one capacitor to the other and radiating disturbing voltages from the line decomposition via the power supply to the grid.

The purpose of the circuitry according to the invention is to reliably eliminate the adverse effects of direct mains supply at low demands on the tolerances and cost of the components used and to achieve minimum energy losses.

According to the present invention, the above-mentioned drawbacks are remedied in accordance with the present invention by re-connecting the starter circuit of the TV decomposition generator, which consists in that a trigger voltage divider is connected to the control electrode of the controlled rectifier. The second resistor of the trigger voltage divider is connected either to the negative pole of the line scanner power supply, or to the negative voltage source powered by the line scan generator, the positive pole of which is connected to the negative pole of the line scanner power supply.

The second resistor of the trigger voltage divider may be either an ohmic resistor or a voltage-dependent resistor, preferably a Zenner diode, or a controlled resistor formed at the collector and emitter terminals of the transistor used. A feedback voltage divider consisting of individual resistors is connected to the transistor base for stabilization, the first resistor of which is connected to the output of the power supply, and at least one other resistor connected to the epojovao point of the feedback voltage divider is connected to reliably disconnect the starter circuit. end to the positive pole of the stabilized row-type power supply, the negative pole of which is connected to the negative pole of the power-supply line of the row-drive exciter voltage.

The advantages of the invention are the achievement of a reliable interruption of the direct mains supply when the line decomposition operation is carried out at relatively low purchase costs using mass production components. In comparison to β, most other solutions of this kind are negligible in the involved circuit. In contrast to all known solutions of this kind, the connection according to the invention makes it possible to switch on the line decomposition generator, and thus virtually the entire receiver, by means of a remote control.

The connection of the atartovaoi circuit of the line decomposition generator of the semiconductor television receiver will be described in more detail in the exemplary embodiment e by means of the attached figures, in which Fig. 1 represents the basic connection and Fig. 2 represents one possible

19S 992 a more specific embodiment of the circuit according to the invention.

According to the basic circuit in FIG. 1, the auxiliary low voltage supply for supplying the line breakdown exciter connected to the power supply voltage U1 is formed by a current limiting resistor 1, a controlled rectifier 2 and an ejector capacitor J. A thyriator is used as a controlled rectifier. In order to control the controlled rectifier 2, force voltages are applied via a trigger voltage divider formed of resistors 4 and 2 '.

In the case of a positive half-wave of the supply voltage, the controlled rectifier 2 opens by a voltage from the trigger divider formed by resistors 4 and 2. The charging current of the smoothing capacitor 2 is limited by a current limiting resistor 1. If the voltage at the smoothing capacitor 2 reaches the level of the peak positive voltage at the control electrode of the controlled rectifier 2, the control rectifier 2 remains closed half-wave in the following positive half-wave. Thus, by suitably selecting resistors 6 and 2 of the start-up voltage divider, the output voltage U3 can be limited if this level does not increase the supply voltage U4. It should be taken into account that the rectifier closes only when the instantaneous voltage value U1 drops to the voltage level U3. so that the voltage at the smoothing capacitor 2 ^will exceed by some value the peak voltage at the resistors a and 2 of the trigger divider according to the magnitude of the capacity of the smoothing capacitor 2 and the current pulse determined by the current limiting resistor 1. After starting the operation of the source U6, the positive pole of which is connected via a blocking diode 6 to the positive pole of the voltage source U2, and whose negative pole is connected to the negative pole of the voltage source U3. In case the voltage U4 is higher than the peak voltage level applied to the control electrode of the controlled rectifier 2, the rectifier remains closed and the exciter power supply is taken over by the power supply U4. In order to select a starting voltage U3 of approximately equal to or comparable to U6, the ground ends of the start-up voltage divider consisting of resistors 4 and 2 can be connected to the negative-voltage source U5. which is activated after the start of line decomposition, for example, by drawing this energy from the line decomposition. This further reduces the positive peak voltage level and reliably disconnects the auxiliary power supply. Instead of an ohmic resistor 2, a voltage-dependent resistor, preferably a Zenner diode, may be used in the trigger voltage divider consisting of resistors 6 and 2. In this case, the output voltage U3 will be less dependent on the tolerance of the force voltage.

A more advantageous circuit compared to the circuit of FIG. 1 and is achieved by the circuit shown in FIG. 2 using a controlled resistor 2 formed at the collector and emitter terminals of the transistor 50. The change from the basic circuit in FIG. for the start-up voltage divider consisting of resistors ⁸⁶ and 28, it then feeds not directly from the mains, but via a rectifier 12 to rectify the force voltage U2, which prevents the negative half-wave from entering the collector of transistor 50. The resistance 2 of transistor 50 is dependent on the control voltage between the base and the emitter of the transistor. This voltage is determined by the feedback voltage divider consisting of the first resistor 8 and the expensive resistor 2 ^to which the output voltage 22 is applied. The stabilizing effect is achieved by using transistor 50 by comparing the output voltage to the base-emitter voltage of the transistor 50.

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When the threshold voltage is exceeded, the resistance 2 of the collector and emitter of transistor 50 drops greatly, thereby suppressing the opening voltage of the controlled rectifier 2 so that it remains closed.

To reliably disconnect the start source, a third resistor 10 of the start inhibit divider connected to the positive terminal of the source U4 is connected to the junction resistor 8 and 2 of the feedback divider. which, in case of power supply to the stabilized power supply, will reduce the separation ratio of the feedback voltage divider consisting of the resistors 8 and 2 of the base voltage control voltage 51 of the transistor 50.

In some cases, for example in the case of remote control or emergency protection, it is expedient to provide the possibility of blocking the starter source with an additional auxiliary voltage U6. In this case, the source of this voltage is connected via the fourth divider resistor 11, to block the start, with the feedback voltage divider node connected to the base 51 of the transistor 50.

Negative poles of sources Ul. U2. UJ, U4 and U5 are connected to a common node to which the ground ends of the trigger voltage divider consisting of resistors 8 and 2 and the feedback voltage divider consisting of resistors 8 and 2 are also connected.

SUBJECT OF THE INVENTION

Claims (5)

1. Connection of a starter decomposition generator of a semiconductor television receiver using a power supply connected to the mains, consisting of a current limiting resistor, a rectifier and a smoothing capacitor, the output terminals of which are connected via a blocking diode a line decomposition generator, characterized in that a trigger voltage divider is connected to the control electrode of the controlled rectifier (2), from whose common node the first resistor (4) leads to a mains voltage supply (U1), the second resistor divider element (5) the trigger voltage is connected either to the negative pole (-U3) of the line decoder power supply, or to the negative voltage source (7) (U5), powered by the line decomposition generator, whose positive pole is connected to the negative pole (-U3) swarm exciters. Start circuit according to claim 1, characterized in that the second resistance element (5) of the start-up voltage divider is formed by an ohmic resistor. 3. The circuit according to claim 1, characterized in that the second resistor element (5) of the trigger voltage divider is formed by a voltage-dependent resistor, for example a Zenner diode. 195 992 The circuit according to claim 1, characterized in that the second resistance element (5) of the trigger voltage divider is formed by a controlled resistance occurring at the terminals of the collector and emitter of the transistor (50) used. A circuit according to claim 4, characterized in that a feedback voltage divider consisting of individual resistors is connected to the base (51) of the transistor (50), the first resistor (8) of which is connected to the output of the power supply (U3). at least one additional starter blocking resistor (10) is connected to the feedback divider connection point, connected at the other end to the positive terminal of the stabilized power supply (U4) powered by the line decomposition whose negative field (-U4) is connected to the negative field ( -U3) a line decomposition exciter power supply. 2 drawings