DE4138493A1 - Degaussing circuit for CRT in TV receiver - has demagnetising coil connected between mains and rectifier via switch opened upon switch=on and closed before current use - Google Patents

Abstract

The demagnetising circuit has a mains powered demagnetising coil (4). The mains terminals (1) are connected to a charging capacitor (6) via a rectifier (5). This supplies a constant voltage (U1) to power the receiver (8). The demagnetising coil (4) is connected between the mains terminals (1) and the rectifier (5) via a switch (S). The switch (S) is opened on switch on (t1) and is closed before the actual current consumption (i1) of the circuit (7) driving the receiver (8). ADVANTAGE - Smaller less expensive circuit with lower power loss.

Description

The invention is based on a circuit according to the Oberbe handle of claim 1.

Such a demagnetization circuit generates after Turn on the TV receiver an alternating current of meh reren Ampere, which switches on after a time of approx. 1 s decays to a value of a few mA. The demagnetization pule is preferably connected directly from the network via a network temperature-dependent resistors, so-called thermistors fed. These thermistors generate by heating and Resistance change the continuously decaying change electricity. Temperature dependent resistors are relatively expensive and also cause a power loss.

The invention has for its object a demagnetizer to create the circuit with few components comes and works with a low power loss.

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

It is known (DE-PS 12 47 380), the demagnetization coil between the power terminals and the input of a bridge to switch rectifier, the output of which is only with a La decenser and a high-resistance resistor is loaded. Then first flows through the demagnetizing coil High amplitude alternating current, which after charging the La decays to a low value. At this The solution is a separate rectifier with a charging capacitor required for the generation of the demagnetizing current Lich. The solution is based on the assumption that the usual existing rectifiers are not suitable for this circuit net is because there the charging capacitor is connected by the  its consumer is loaded and therefore the alternating current in does not subside the rectifier as it does for the Ent magnetizing current is necessary.

The invention is based on the knowledge that in one TV receiver with switching power supply which usually exists power rectifier to generate the operating voltage unexpectedly suitable for the television receiver, a decaying alternating current on its input side generate, which are used as demagnetizing current can. This is due to the following peculiarity of new types Switching power supplies.

Novel switching power supplies go through after switching on the power switch first in a so-called initialization phase. Only a very slight equal flows in this phase current of a few mA to charge a capacitor. These Phase is used for the half present in the switching power supply conductors defined relationships with regard to preloads adjust and a destruction of the components in the one to avoid switching phase. This initialization phase is ongoing longer than charging the charging capacitor in the power supply. The current is so low, however, that on the entrance side of the rectifier is a sufficiently small value for the current used for demagnetization results. If the init Alization phase has ended after approx. 3 s and the startup phase se and the transition to normal operation with nominal current consumption me, the demagnetizing coil is already through bridged the switch so that the current through this coil then is zero. In the solution according to the invention a special one for a television receiver with a switching power supply Peculiarity of the switching power supply in an advantageous manner uses in a circuit-technically simple way the on egg a small decaying demagnetizing current testify. An alternative is the switching power supply from a microprocessor or via a time constant element consciously delayed to switch on until its nominal  current consumption only begins when the demagnetizer current decayed to the small value and with the scarf ter is finally switched off. The delayed closing of the Switch can also be in the TV receiver in the general existing microprocessor. But it is also possible to assign a separate switching element to the switch NEN, e.g. B. an RC element that the closure of the switch after a defined time.

The circuit according to the invention is particularly cheap because in In contrast to known circuits, no temperature-dependent resistors (thermistors) are required. Advantageous is also that the demagnetizing current through the scarf ter is completely switched off. This is particularly important for large picture tubes with a screen diagonal of 85 cm or for picture tubes with an aspect ratio of 16: 9. The Circuit does need a switch. This switch is but necessary anyway with the large picture tubes mentioned Lich, because the demagnetizing current there completely abge must be switched. Another advantage is that the demagnetization coil in addition to limiting the Charge currents in the charging capacitor when switching on serve can. A relatively expensive high resistance required so far Power between the power terminals and the input of the DC richters is then saved. Because no loss effecting temperature-dependent resistors be, the efficiency of the overall circuit will he increases.

The anyway when switching on the television receiver from the network flowing charging current for the charging capacitor is at the Er So in an advantageous manner, in addition, demagnetization used for the picture tube.

Exemplary embodiments of the invention are described below hand of the drawing explained. Show in it

Fig. 1 shows an embodiment of the invention,

Fig. 2 curves to explain the operation of the circuit of FIG. 1 and

Fig. 3 shows a modification of the circuit of FIG. 1.

In Fig. 1, the power terminals 1 are connected via the power switch 2 , the fuse 3 and the demagnetizing coil 4 to the power rectifier 5 , the output of which is grounded via the charging capacitor 6 and supplies the operating voltage U1 for the switching power supply 7 . The switching power supply 7, it produces the operating voltage for the television receiver circuit 8 , to which the picture tube 9 and the speaker 10 are ruled out. The microprocessor 11 controls the switching power supply 7 via line 12 , in particular different operating phases when switched on, and also via line 13 various functions of the television receiver circuit 8 with respect to volume, brightness, contrast, channel selection and the like. At the input of the microprocessor 11 is Infra red remote control receiver 14 connected, on whose Emp catch diode 15 the remote control signal 16 arrives from a remote control unit, not shown. The microprocessor 11 is also switched on in standby mode. For this purpose, a second switched-mode power supply 17 of low power is provided, the input of which is connected to the power terminals 1 and the output of which supplies the operating voltage U2 for the receiver 14 and the microprocessor 11 .

The mode of operation of the demagnetization circuit integrated with the network is explained with reference to FIG. 2. At the time tO, the television receiver 8 is switched off by the open power switch 2 , so that no demagnetizing current iM flows in the demagnetizing coil 4 . The switch S is initially open. At time t1, the power switch 2 is closed. Since the charging capacitor 6 is initially discharged, a charging current flows into the charging capacitor 6 starting from t1. Since this charging current flows through the demagnetizing coil 4 , it simultaneously acts as a demagnetizing current iM for the picture tube 9 . By charging the charging capacitor 6 , the current iM slowly decreases in the desired manner and finally reaches the desired small final value of approximately 5 mA. The switching network part 7 is not yet switched on by the microprocessor 11 , so that the charging capacitor 6 is not discharged. At time t2, the microprocessor 11 generates the switching voltage 18 , which closes the switch S. This completely deactivates the demagnetizing current iM. This is particularly necessary for large picture tubes with an aspect ratio of 16: 9 or a screen size of 84 cm in order to avoid interference on the screen. From now on, the switch S remains closed for the entire operating period of the television receiver until the television receiver is switched off again by opening the mains switch 2 . At the time t3, about 2-3 s after t0, the switching power supply 7 is switched on by the microprocessor 11 via the line 12 , so that a current i1 from the charging capacitor 6 now flows into the switching power supply. However, this current desirably causes no demagnetizing current iM through the coil 4 , since the switch S is now closed.

The switching power supply 7 can also be designed independently of a microprocessor so that it only takes a very low current of about 1-3 mA for a time of about 2-3 s after switching on during a so-called initialization phase. This current is used only for the preparation and generation of bias voltages for semiconductor components at risk when switched on. The current is so low that it does not cause any appreciable discharge of the charging capacitor 6 and therefore does not cause any significant demagnetization current iM. In principle, this current could already start when switching on at time t1. The demagnetizing current iM would then still decay to a sufficiently low value.

The small switched-mode power supply 17 is connected to the mains terminals in front of the coil 4 . This ensures that, regardless of its size, the current received by the switched-mode power supply 17 from the network does not cause a demagnetizing current M. In Fig. 1 it is assumed that the delayed closing of the switch S is controlled by the microprocessor 11 .

Fig. 3 shows an embodiment in which the switch S is assigned its own switching element, which causes the delayed actuation of the switch S and works independently of a microprocessor or a switching power supply. The switch ter S is formed by the shunt contact a1 of a relay. Its field winding A is connected to the capacitor 21 , to which the power terminals 1 are connected via the resistor 19 and the diode 20 . When switching on at time t1, the voltage U2 across the capacitor 21 is still zero, and thus the contact a1 according to FIG. 1 is open. Starting from t1, the capacitor 21 is charged so that the voltage U3 rises. At time t2, U3 reaches a value at which the relay picks up and contact a1 is closed. Otherwise, the mode of operation is as in Fig. 1. The Wi resistor 19 is used to reduce the final stationary value of U3, so that the capacitor 21 can have a lower voltage resistance. The resistor 19 preferably has a few kOhm, the capacitor 21 some 100 uF and a dielectric strength of 63 volts.

The delayed activation of the switching power supply 7 at t3 ge according to FIG. 2 is also not by a microprocessor, but by its own control circuit. The switching power supply 7 has a control terminal 22 whose voltage Vcc activates the switching power supply 7 . The switched-mode power supply 7 only goes into normal operation with current consumption i1 when the voltage Vcc at the control terminal 22 reaches a value of approximately 10 volts. A mains connection 25 of the rectifier 5 is via the relay contact a2 and the RC element from the opposing stand 23 and the capacitor 24 to the control input 22 is connected. Relay contact a2 is operated simultaneously with relay contact a1. Only from t2 can the voltage Vcc rise at the control input 22 and activate the switching power supply 7 after a certain time. This ensures that the activation of the switched-mode power supply 7 and the start of the current i1 only take place after the demagnetization current iM has been switched off at t2.

The relay contact a2 can also be omitted. Then the time constant 23/24 must be larger than the time constant 19/21 , so that the switching power supply 7 is activated by the voltage Vcc after the relay contact a1 is closed at time t2.

The switch S can basically be formed by a relay, a transistor, a thyristor, a triac or a corresponding component. The demagnetizing coil 4 is dimensioned such that the coil 4 additionally limits the charging current into the charging capacitor 6 after switching on at time t1. The limiting resistor for the charging current otherwise provided between the fuse 3 and the rectifier 5 can then be omitted. This not only saves the cost of the resistor, but also eliminates the power loss that otherwise occurs at the resistor.

Claims (12)

1. Circuit for demagnetizing the picture tube ( 9 ) in a television receiver with a demagnetizing coil ( 4 ) fed by the mains, in which the mains terminals ( 1 ) are connected via a rectifier ( 5 ) to a charging capacitor ( 6 ), which has a direct voltage ( U1) for a switching power supply ( 7 ) supplying the receiver ( 8 ), characterized in that the demagnetizing coil ( 4 ) is connected between the power terminals ( 1 ) and the rectifier ( 5 ) and is bridged by a switch (S), which is open when switching on (t1) and closed before the nominal current consumption (i1) of the switching power supply ( 7 ). 2. Circuit according to claim 1, characterized in that the switch (S) of a switching power supply ( 7 ) and / or the receiver circuit ( 8 ) controlling microprocessor ( 11 ) is controlled ( Fig. 1). 3. A circuit according to claim 1, characterized in that the switch (S) is an automatically acting switching element with delay after switching on th ( 19 - 21 ) zugeord net ( Fig. 3). 4. A circuit according to claim 1, characterized in that the switch (S) is actuated by a switching voltage derived from the switching power supply ( 7 ). 5. A circuit according to claim 1, characterized in that the switching power supply ( 7 ) is designed such that after switching on during an initialization phase it only takes up a very small current of a few mA and only after a few seconds in the normal operation Rated current consumption (i1). 6. Circuit according to claim 5, characterized in that the switching power supply ( 7 ) has a control input ( 22 ), the voltage (Vcc) of which activates the switching power supply ( 7 ). 7. Circuit according to claim 6, characterized in that a power terminal or a connection of the rectifier ( 5 ) via a time constant element ( 23 , 24 ) to the control input ( 22 ) of the switching power supply ( 7 ) is connected ( Fig. 3). 8. A circuit according to claim 6, characterized in that a power terminal or a connection of the rectifier ( 5 ) via a switch (a2) to the control input ( 22 ) of the switching power supply ( 7 ) is connected, which is open when switching on and after Decay of the demagnetization current (iM) is closed ( Fig. 3). 9. A circuit according to claim 1, characterized in that the network input of a second, for a standby operation switching power supply ( 17 ) before the demagnetization coil ( 4 ) to the power terminals ( 1 ) is ruled out ( Fig. 1). 10. A circuit according to claim 1, characterized in that the switch (S) as a relay, transistor, thyristor or Triac is formed. 11. Circuit according to claim 3 and 10, characterized in that the network terminals ( 1 ) via a rectifier ( 20 ) and an RC element ( 19 , 21 ) are connected to the excitation winding (A) of the relay ( Fig. 3) . 12. The circuit according to claim 1, characterized in that the demagnetizing coil ( 4 ) is dimensioned such that it additionally acts as a series resistor for limiting the La destroms of the charging capacitor ( 6 ).