DE2835613A1 - Demagnetising circuit for colour TV CRT - connects capacitor to coil by relay whose excitation coil is connected to heating filament and transformer secondary tapping - Google Patents

Abstract

The demagnetising circuit has the changeover contacts (a) of a relay (A) connecting the demagnetising capacitor (8) in one position to the demagnetising coil (11) and in the other position to a +700 V supply. The +700 V supply is drived from the receiver's +1100V supply using a two-resistor voltage divider (9, 10). The relay's excitation coil is connected at one end to the tube's heating filament (5) and at the other via a diode (7) to a tapping on the secondary winding (2) of the line transformer (1) (This secondary winding is coupled at one end to one end of the heating filament and at the other end via a diode and ballast resistor (4) to the other end of the heating filament).

Description

Circuit for demagnetizing the picture tube in a color

tv receiver In a color television receiver, as is well known, the The picture tube is demagnetized every time it is switched on to avoid errors in the color purity Magnetization of metal parts inside the picture tube, e.g. by the earth's field, to avoid.

For this purpose it is known (DE-PS 12 70 074), the conical piston to surround the picture tube with two saddle-shaped coils and these each when switched on to feed the receiver with an alternating current. This one has a big one at first Amplitude of e.g. 5 A and sounds to zero or one in the course of 1 to 2 seconds very small value.

Because of the relatively high current required, the Degaussing coil directly from the mains connection terminals of the receiver via temperature-dependent Resistors fed that cause the desired drop in the current. Since here the degaussing coil is connected directly to the mains terminals for safety reasons considerable effort is required to isolate the degaussing coil.

This Schlfierigkeit can be avoided if the color transmitter is provided with a mains transformer. This solution is therefore in practice undesirable because such a power transformer is a relatively expensive and heavy one Component is and also generates disruptive magnetic fields.

It is also known (DE-OS 22 51 936) the Entniagnetisierungs coil to feed from the line output stage of the television receiver.

The demagnetizing current then has the line frequency of about 16 kIlz. On the other hand, because the degaussing coil has a considerable inductance of about 30 ml, a relative high voltage of approx. 10000 V can be made available. Same difficulty exists in TV receivers with a switched-mode power supply. A switching power supply causes also a galvanic separation of the receiver circuit from the network. It works but also with a high frequency of the order of 20 to 30 kliz.

There is also a de-magnetization circuit known (US-PS 29 62 621), in which a capacitor is connected to a DC operating voltage when the receiver is switched on applied and when switching off the receiver parallel to the degaussing coil is switched. The capacitor and the degaussing coil then form one Oscillating circuit, the oscillations being dampened by the voltage on the capacitor that is stimulated. fade to zero after a few periods. With this solution The degaussing coil remains permanently disconnected from the mains.

The elite magnetization does not take place when switching on, but when switching off the receiver. Such a circuit is practically not applicable, because then changes occurred between two operating periods of the receiver in the magnetization of the. Metal parts of the picture tube when the receiver is switched on cannot be eliminated and thus the image is defective during a power-on period can be. These errors are only eliminated at the end of a switch-on period.

The invention has for its object a demagnetization circuit to create the last-mentioned type, in which the said capacitor in each case immediately after switching on the receiver at the right time to the demagnetization Rungsspule is applied for the purpose of demagnetization.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are described in the subclaims.

In the invention, the property of a bridge circuit is advantageous exploited, initially a current in the diagonal branch in the unbalanced state to generate the bridge, which brings a relay switched on there to attract. During the start-up time of the receiver, the bridge is equalized by a voltage-dependent Component automatically, so that finally the current in the diagonal branch is so small, that the relay drops out. With a normally closed contact of the relay, the will in the meantime charged capacitor is connected to the degaussing coil.

Such bridge circuits that are initially unbalanced and get into the balanced state after switching on are actually for the Demagnetization of the picture tube known (DE-OS 19 62 382). But Dqrt is in the Diagonalweg the bridge is the degaussing coil itself and not the winding of one of the aforementioned Capacitor switching relay.

The invention is based on the drawing of an exemplary embodiment explained. FIG. 1 shows a basic circuit diagram of the invention and FIG. 2 the voltage curve on the charged capacitor.

In Figure 1, the line transformer 1 contains a fieizwick 2, which over the diode 3 and the series resistor 4 are connected to the filament 5 of the picture tube 13 is. The parts 3,4 have the purpose supplied by the winding 2 Adjust the voltage to the heating voltage required for the filament 5 of the picture tube 13. Between the tap 6 of the winding 2 and the connection point of the filament 5 the series circuit of the diode 7 and the relay winding is connected to the resistor 4 A, to which a relay changeover contact a belongs. The relay contact a can the capacitor 8 between an operating voltage obtained by the voltage divider 9, 10 of 700 V and the degaussing coil 11 switch. The voltage divider is 9.10 to the terminal of the screen grid voltage of the picture tube 13, in particular to a tap the high-voltage cascade for the picture tube 13 is connected.

The mode of action is as follows. When the color television receiver is switched off the winding A is de-energized, and the contact a is in the solid line Position The capacitor 8 and the coils 11 form a currentless parallel resonant circuit. When the receiver is switched on, the voltage of + 1,100 V appears and thus also the voltage of + 700 V practically instantaneously. On the other hand, the filament is 5 still cold and relatively low resistance. The through the two winding parts of the winding 2 on the one hand and the filament 5 and the resistor 4 and the diode 3 on the other hand The bridge circuit formed is dimensioned so that the bridge circuit when the filament is cold is not matched. A current therefore flows through the winding via the diode 7 A. This is so large that the relay picks up and the contact a in the dashed line The position shown is turned over, this also happens immediately after switching on Recipient.

The capacitor 8 is now charged according to FIG. 2, accordingly the time constant formed by the circuit with the resistors 9, 10. To The capacitor 8 has reached the final value of the voltage of about 700 V for about 0.6 s. At this moment the filament of the picture tube 5 has also reached its final state warmed up. In this final state, the bridge circuit is now so far balanced and the current through winding A accordingly sunk so far, that the relay drops out and the contact a in the drawn position falls behind. Now the capacitor charged to the voltage of 700 V is 8 connected in parallel to the degaussing coil 11. This creates the one in figure Demagnetizing current 12, shown in FIG. 2, decaying to zero through the coil 11, the frequency of which is determined by the resonance frequency of the oscillating circuit 8, 11 is. After about 10 ms this current has decayed to zero. The current 12 causes the desired demagnetization immediately after switching on the color television receiver.

The image reproduction on the picture tube 5 does not begin until later, after about 3-4 s, so that the degaussing process appears on the screen in the desired manner is not visible.

The circuit has the following advantages. The capacitor 8 is in each case always only a short time on voltage, namely only about 1 s after switching on the Recipient. The entire remaining time during the operating period of the receiver and the capacitor 8 is voltage-free during the switch-off period. In addition, the demagnetizing current sounds completely to zero because in the oscillating circuit 8, 11 except for the initial charge of the capacitor 8 no more energy is fed in. Finally, the Current through winding A during the operating period of the receiver is practical equal to zero, because the bridge circuit is practically balanced for this case This results in overall good efficiency and low power consumption the entire degaussing circuit.

Claims (6)

Claims ii. Circuit for demagnetizing the picture tube in a color television receiver, in which a charged by an operating voltage Capacitor for the demagnetization process with a switch parallel to the demagnetization ti sierungsspule is placed, by, çekenll shows, .that the switch by a Closed-circuit contact (a) of a relay is formed, the winding (A) of which in the diagonal branch one that was not calibrated when the receiver was switched on and is in the stationary switched-on state balanced bridge circuit (2-5). 2. Circuit according to claim 1, characterized in that a member sec the bridge is formed by the filament (5) of the picture tube (13). 3. A circuit according to claim 2, characterized in that the filament (5) is connected to a transformer winding (2) via a series resistor (4) and the relay winding (A) between a tap (6) of the transformer winding (2) and the Connection point between Ileizfaden (5) and series resistor (4) lies. 4. A circuit according to claim 3, characterized in that the transformer winding is a winding (2) of the line transformer (1). 5 circuit according to claim 3, characterized in that in series a diode (3.7) is connected to the series resistor (4) and / or the relay winding (A). 6. A circuit according to claim 1, characterized in that the relay contact is a changeover contact (a) that connects the capacitor (8) when the relay has dropped out the degaussing coil (11) and with the relay energized with the operating voltage (+ 700 V) connects.