DE2449280B2 - Feed circuit for televisions - Google Patents

Description

The invention relates to a supply circuit for television sets with a controllable semiconductor switch to interrupt the supply current in the event of overloads, to which a resistor is connected in parallel, via that the low supply current flows during a start-up phase.

Televisions have a general central feed circuit through which the for the operation of the Device required electrical energy is taken from the supply source.

Feed circuits are known in which the feed circuit is in series with the power switch controllable semiconductor switch lies. The control electrode of the semiconductor switch switched on in the current direction is in a suitable manner, which is not of further interest here, with the horizontal deflection circuit tied together. So that the supply current can flow after the power switch is closed, the controllable semiconductor switch, the z. B. is a thyristor, are switched through. For this purpose, the known circuit several circuit measures provided: The thyristor is a high resistance connected in parallel. The current through this resistor is very small and sufficient just off to charge a downstream capacitor to such a voltage that the connected connected deflection circuit generates the control current required to switch the thyristor through will. The reason why the thyristor is controlled from the downstream deflection circuit is in the function of the thyristor. This should be in the event of malfunctions such. B. short circuits, the supply interrupt immediately and quickly.

With such a circuit there is a certain start-up delay for those connected downstream of the thyristor Circuits a, dtren duration essentially by the value of the resistor in parallel with that Thyristor is intended.

The duration of the start-up delay should be long enough that z. B. the output voltage of the line oscillator one for the proper control of the deflection switch has reached a sufficient value.

There are contradicting requirements for the choice of the resistance value; on the one hand is a noteworthy one Delay only possible with relatively high resistance values, on the other hand there is a resistance that is too high the risk that the z. B. for the oscillation of the line deflection required control voltage on Output of the line oscillator is not reached. Add to this the problems caused by the inevitable Tolerances of all components in question and their interaction occur.

The object of the invention is therefore to provide a precisely definable delay time using simple means and then to ensure a reliable oscillation of the deflection circuit.

This object is achieved according to the invention in that the resistor is used as a resistor negative temperature coefficient is formed, the cold resistance of which results in such a small current where the deflection circuit remains idle and its Varm resistance value is so low is that the current flowing then ensures a reliable oscillation of the deflection circuit.

The arrangement also has the great advantage that the delay time also from the point of view the demagnetization can be optimally selected, d. H. the demagnetization process is complete, before the deflection circuit starts to oscillate. This z. B. the disturbing influences on the quality of the Color rendering as a result of the superimpositions of the fields of the demagnetizing current that occur and the Abienkstromes switched off.

According to a further embodiment of the invention it is provided that a resistor with a solder fuse is connected in parallel with the thyristor and in series with the resistor with a negative temperature coefficient.
This measure ensures that, for. B. if the parallel thyristor fails, no damage occurs in the circuit.

Further details and advantages of the invention can be found in the following description of the drawings can be removed.

F i g. 1 shows an embodiment of the circuit according to the invention;

F i g. 2 shows an oscillogram to illustrate the time processes.
At terminal 1 is the AC mains voltage of z. B. 220 V 50 Hz. The input circuit branches at this terminal. One line leads to the degaussing circuit labeled DG. This consists of the resistor arrangement PTC with positive temperature coefficients, the demagnetizing coils Wi and W2 and an auxiliary resistor RS. To explain the function, it should only be mentioned here that after switching on the device, a large demagnetizing current flows through the windings WX and W2 initially, ie for about 1 to 2 seconds, which then heats up under the action of the PTC resistors and become high-resistance, as well as drops to a low permanent value with the help of the resistor R 8. It could also be switched off entirely by suitable means.

The other circuit leads from terminal 1 via fuse 5 / to the actual feed circuit. Only the circuit elements which are of interest in the context of the invention are of this supply circuit shown. So it's a strong one

b5 simplified, schematic representation.

From the output of fuse 5; leads the circuit via the resistor R 1 and the downstream diode D 1, ie the mains rectifier to a branching

point 2. At this point 2 the thyristor Th is connected with its cathode. From the anode of the thyristor Th , the circuit leads via a branch point 3 and the screen resistor R 4 to the output terminal 4 of the Speiseschaltui g. At this terminal 4 is the supply voltage for the essential functional units, such as. B. the deflection circuits and the feed circuit for the picture tube. The filter capacitor C3 is connected to point 3 and the filter capacitor C4 is connected to terminal 4.

The control circuit of the thyristor Th runs from its control electrode 6 via a resistor R 5 and a capacitor CS to terminal 5.

The resistor R 5 is used as a limiting resistor for the control circuit, the capacitor is used to isolate the potential. From terminal 5, the control circuit leads in a manner not shown, for. B. for horizontal deflection circuit.

The resistor R6, which is also connected to the control electrode 6, is used to determine the potential of the control electrode 6. This circuit described up to now is known up to the terminal 5.

It is also known that a resistor is connected in parallel to the thyristor Th between points 2 and 3, the function of which has already been explained in the introduction to the description. It was also explained which disadvantages are associated if this resistor, as is known, is designed as a simple, high-resistance resistor.

According to FIG. 1, a resistor NTCmh with a negative temperature coefficient is now connected between terminals 2 and 3. It is advisable to connect the resistor Λ 7 in series, which contains a fuse that can be soldered out. Its only function is that, in the event of a failure of circuit parts, which does not yet lead to a claim from the mains fuse S /, the device is largely de-energized by triggering the soldering fuse. This is the case, for example, if the control voltage at the electrode 6 for the thyristor fails.

The mode of operation of the invention is explained below with the aid of the oscillogram according to FIG. 2 explained.

In Fig. 2 the time is plotted on the abscissa, where the scale is selected with 500 ms per division.

Two values are plotted on the ordinate, for which two zero or reference values apply. For the voltage UBgWt the upper zero value and a scale of 50 volts per division, for the voltage UGTH 1 the lower zero value and the scale 5 volts per division apply.

The supply voltage at terminal 4 is designated with UB.

After switching on the television set, the mains voltage is applied to terminal 1.

The thyristor Th is blocked. A small current therefore flows through the resistor R 1, the rectifier Dl and the resistor NTC as a charging current into the filter capacitors C3 and C4. The charging voltage on the capacitor C4 and consequently on the terminal 4 remains so low because of the low charging current, ie because of the high-ohmic state of the resistor NTC , that the circuit parts connected to the terminal 4 remain inoperative.

The resistor NTC, which in a practical circuit example has a cold resistance of around 15 kO. heats up due to the low current flowing through it. As the temperature rises, the resistance value drops, with the warm resistance still around 1 kΩ. or less. This can be seen in FIG. 2 from the slightly rising characteristic curve UB . As can also be seen, this process takes up to 3 seconds.

After this time has elapsed, the voltage on capacitor C4 has _{risen to around 20-30 V v} 20, as can be seen. This is sufficient to let the deflection circuit used in the practical implementation, which is not shown here, start to oscillate. This creates the return pulses arranged at terminal 5 in the horizontal deflection circuit. These I npulse reach the control electrode 6 of the thyristor Th, which is thus controlled to be conductive. From this moment on, the full operating voltage of approx. 270 V is applied to terminal 4.

The resistor NTC is to be regarded as short-circuited by the thyristor Th , taking into account the resistance ratios, and returns to the cold state.

The lower voltage curve UGTH 1 shows the time profile of the control voltage for an electrical switch used in the practical circuit in the deflection circuit (not shown). This control voltage is generated by an oscillator that is not fed from the feed circuit shown here.

The only thing of interest here is the knowledge that this control voltage also starts with a delay, that but this delay has no adverse effect, since this time has passed before the Intended delay time of the main supply (curve / ^ has expired.

In the time sequences shown here, the horizontal deflection circuit is connected to terminal 4, from which other circuit parts are fed. In principle, however, other circuits are also connected can be connected to terminal 4.

The filter elements C3 and C4 each had 200 μΡ and the resistor R 4 had about 15 in the exemplary embodiment.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Feed circuit for television sets with a controllable semiconductor switch for interruption of the supply current in the event of overloads, to which a resistor is connected in parallel, via which the low supply current flows during a start-up phase, characterized in that the Resistance is designed as a resistor with a negative temperature coefficient, its cold resistance results in such a small current that the deflection circuit remains idle and whose warm resistance value is so low that the current flowing then causes a certain oscillation of the Deflection circuit guaranteed. 2. Feed circuit according to claim 1, characterized in that in parallel to the thyristor and in In series with the resistor with a negative temperature coefficient, a resistor with a solder fuse is switched.