DE2056156A1 - Circuit arrangement for heating a cathode ray tube, preferably a directly heated television picture tube or an oscilloscope tube - Google Patents

Description

Circuit arrangement for heating a cathode ray tube, preferably a directly heated television picture tube or an oscillograph tube The invention relates to a circuit arrangement for heating a cathode ray tube, preferably a directly heated television picture tube or an oscillograph tube, whose cathode is fed a signal. Such a tube must not be used directly Mains-frequency electricity from a mains transformer can be heated, as both the capacitive The load on the cathode would be too great, at which the signal is fed in at the same time is, as well as in a disturbing way the 50 Hz mains frequency as so-called mains hum would be visible on the screen.

It is known per se, especially in the case of television receivers, the heating current for the picture tube from the secondary winding, for example one with a toroidal core provided transformer, its primary winding in the deflection circuit the line end stage. In this known circuit for a picture tube heater the tube with line frequency voltage of, for example, 0.5 Veff. and one Heated electricity of about 0.63 keff. Those currently approved by the tube manufacturer Tolerances are consistently i 10%. The toroidal transformer must therefore be designed in this way be that in the event of any fluctuations in the operating voltage of the device, the voltage on the secondary winding of the transformer does not exceed + 10%.

Fluctuations in the operating voltage can be caused, for example occur that the regulator to adjust the stabilized voltage in manufacturing has been turned up fully, or it is the regulating series transistor of the power supply unit of the Device defective, so that it switches through and so the full input voltage at the output of the power supply unit.

One way of realizing the requirement, a toroidal transformer to be trained so that even with fluctuations in the operating voltage of the device, the the secondary winding of the transformer detachable heating voltage within the + 10% tolerance remains, could consist of a toroidal core with a rectangular hysteresis curve to choose and to place the working point on the kink. If the deflection current is higher, which is fed to the toroidal transformer from the flyback stage, it can then to no inadmissibly high voltage rise in its supplying the tube heating voltage Secondary windings come because the toroid is operated in saturation. but apart from the fact that the stabilizing effect is not sufficient, this has Method has a major disadvantage. Iron cores with a rectangular hysteresis curve, and Although preferably ferrite cores, they have a broad, large-area B-H curve. That means but that these iron cores have considerable losses and therefore become very warm.

This heating in turn affects the magnetic properties such cores, so that the desired stabilization for the cathode ray tube required heating voltage is not fully reached.

There are toroidal cores that are wound from soft magnetic tapes and which therefore have low losses, although they have a rectangular shape their hysteresis curve.

However, such cores are very expensive. A high number of turns for the Choosing the primary winding in order to be able to drive the core far into saturation is also disadvantageous because due to the high inductance of such a primary winding, which is in series with the line deflection coil in television receivers, a considerable Part of the amplitude of the line deflection voltage is lost.

With the aid of the invention, the disadvantages described above are now eliminated in the case of a transformer for heating a directly heated cathode ray tube This avoids both occurrence of high heat loss in the transformer core avoided as well as a primary winding with high additional inductance which reduces the amplitude of the line deflection voltage.

According to the invention, the above object has now been achieved by that the heating current for the tube supplying transformer preferably with a such an iron core designed as a toroidal core is provided, which has a narrow B-H surface and its hysteresis curve has a steep course and the top and bottom gradually merges into the saturation area, whereby this transition is not just through the line deflection current, but also, and preferably, by an external field is effected.

To generate the external field, according to a further invention, the as Toroidal core formed transformer core provided with a third winding, through the direct current is conducted, with which the core is premagnetized in a direct current manner and which is dimensioned in magnitude and polarity in such a way that this premagnetization a stable tube heating voltage that is independent of fluctuations in the operating voltage of the device can be removed from the secondary winding of the transformer.

This third transformer winding is then advantageously in Series with the regulating series transistor in the stabilized operating voltage power supply of the device. In order to reduce the heating voltage also from fluctuations in the beam current To make largely independent in the cathode ray tube is according to another expedient addition to the subject of the invention of the transformer core with a fourth winding, which is in series with a choke and the collector of the Line output transistor is placed. This means that this winding has a direct current component and a line-frequency alternating current component, both of which are directly proportional are the jet stream. With regard to the number of turns and polarity, it is designed that the alternating current component causes such positive feedback to the secondary winding, that the residual control errors caused by the jet current fluctuations of the regulating DC currents are compensated.

Details of the invention are set out below with reference to in the drawings illustrated embodiments described in more detail.

1 shows a circuit example known per se for the primary-side supply of a toroidal transformer through a line output stage and for heating current for a cathode ray tube, which can be removed from the secondary winding; 2 shows a rectangular hysteresis curve of a ferrite core; 9 shows a circuit example according to Fig. 1, but supplemented according to the invention by a to a direct current source connected third winding on the toroidal core of the transformer; Fig. 4 course the hysteresis curve of the ring core selected according to the invention for the circuit example according to Fig. 3; FIG. 5 shows an example of a circuit according to FIG. 3, expanded around a fourth winding on the toroidal core of the heating current transformer; Fig. 6 that Circuit example according to FIG. 5 in connection with a shown schematically stabilized operating voltage power supply of a television receiver.

In Fig. 1 is a known circuit for extraction schematically of the heating current for a directly heated cathode ray tube 3 is shown. Included is the primary winding 4 of a bing core transformer used for generating heating current 2 via the series connection of the line deflection coil L t and the capacitor C 1 with a line output stage shown here as block 1, for example a television receiver, tied together. The secondary winding 5 of the toroidal core transformer 2 can then have a line frequency Heating current for the directly heated cathode ray tube 3 can be taken.

In Fig. 2, the hysteresis curve of a toroidal core is shown, with that in a circuit according to FIG. 1 the requirement for a largely constant Heating voltage could be met despite fluctuating operating voltage in the device. In this toroidal core, the hyteresis curve is largely rectangular in shape, and the Working point a lies on the kink. So would a higher current in the line output stage 1 and thus also occur in the primary winding 4 of the heating current transformer 2, ao can therefore not have a higher voltage in the secondary winding 5 and thus also no higher heating current arise because a toroidal core with a hysteresis curve according to Fig. 2 is operated in saturation.

But iron cores, preferably the ferrite cores used throughout, have a hysteresis curve with a large B-H area and therefore also have considerable Heat losses.

As is well known, the high temperature increases the magnetic properties such iron cores severely impaired, so that the desired stabilization of the The heating voltage to be taken from the transformer is also not optimally attainable. One could use the well-known ring cores wound from soft magnetic strips use that have low losses, although they are also rectangular Have a hysteresis curve that includes a large B-H area. Such ring bodies however, they are very expensive. In addition, the primary winding then required with a high number of turns another, quite considerable disadvantage occurs. Through the high inductance of such a multi-turn primary winding, for example in a television receiver in series with the line deflection coil L 1 (Fig. 1), namely, a not inconsiderable part of the amplitude of the line deflection voltage goes lost.

In the circuit diagram of FIG. 3, the inventive solution is now present problem with the direct heating of the cathode ray tube 3 in the transformer 2 provided for this purpose, a toroidal core 2b with a steep hysteresis curve and narrow B-H area according to FIG. 4 is used, the top and bottom gradually merges into the saturation area and in which this transition is not only caused by the Line deflection current from the line output stage 1, but also, and preferably is controlled by an external field by means of a third winding 6. This winding 6 on the toroidal core 2b is via throttles L 3 and L in this exemplary embodiment 4 connected to a direct current source 7.

The toroidal core 2b is premagnetized by the direct current via the winding 6 and thereby the AC operating point a on top of the flat part of the B-H surface pushed, as shown in Fig. 4, where there with b the size of the premagnetization and h denotes the magnitude of the direct bias current. If now Operating voltage fluctuations occur in the device, arise in a circuit arrangement According to FIG. 3, there are no significant changes to the changes that can be removed from the secondary winding 5 Heating voltage. You can use a toroidal transformer with the drawn windings 4, 5 and 6 lay out optimally, i.e. coordinate these windings 8o with one another that a stable voltage of, for example, 0.5 Veff and an equally stable current for example 0.63 Aeff. for direct heating of the cathode ray tube 3 on the secondary winding 5 can be removed with the permitted tolerance of + 10%. The toroidal core 2b is not continuously driven through and through alternating current phase also works because of its narrow W-H area with the lowest possible losses and accordingly less heating. Han can do this with relatively cheap toroidal cores get along. For the primary coil 4 lying in series with the line deflection coil L 1 only a few turns are required in this circuit design according to the invention, so that the series inductances of primary winding 4 and line deflection coil L 1 cannot have any adverse effects on the image width.

6 shows the circuit arrangement with a fourth winding 11 shown on the toroidal core 2b of the heating current transformer 2.

To this extent, it represents an expedient further development of the arrangement according to Fig. 3, as with the help of the winding 11 residual control error of the heating voltage regulating direct currents can be compensated. As from the detailed circuit diagram According to FIG. 6, the one used to regulate the heating voltage is used throughout Winding 6 in series with the regulating series transistor T 1 of the stabilized operating voltage power supply 10 of the device in question, e.g. a television set. This causes the whole to flow Direct current of the device through the winding 6, so that any changes in the operating voltage have the consequence that in addition to the line output stage 1 also all others with direct current supplied consumers of the circuit, so also the winding 6 more or less Consume direct current. As a result, the toroidal core 2b of the transformer 2 takes different Saturation states and thus has a balancing effect on the secondary winding 5 induced heating voltage for the cathode ray tube 3.

Since now, however, the direct current flowing in the regulating winding 6 depends on the beam current in the cathode ray tube and this in turn depends is caused by changes caused by the respective brightness and contrast settings DC fluctuations, the saturation states fluctuating in the toroidal core 2b of the transformer 2 cause and thus also fluctuations in the induced in the secondary winding 5 Heating voltage. If the beam current increases, the direct current in the transformer winding also increases 6. The toroidal core 2b is brought more into saturation and the heating voltage on the Secondary winding drops. As the beam current decreases, so does the direct current usually winding 6 less.

The saturation of the toroidal core 2b decreases and that in the secondary winding 5 induced heating voltage for the tube 3 increases. To these fluctuations largely to compensate is, according to the circuit diagram in Fig. 5, a further winding with 11, is arranged on the toroidal core 2b of the transformer 2.

The circuit diagram of FIG. 6 then shows how the regulating winding is made 6 and the compensation winding 11 can be connected, for example, in terms of circuitry. From the circuit diagram it can be seen that the line output stage 1 stabilized its Operating voltage UStab is obtained from the power supply unit 10. A regulator 8 in this power supply is used to set the stabilized mains voltage UStab, and with 9 a control and control element. The compensation winding 11 is located with a choke L 2 and the collector of the line output transistor T 2 in series. The Transistor collector in a known manner via the inductor L 2 to the stabilized Tension laid. A direct current component then flows through the compensation winding 11 and a line frequency alternating current component, both directly proportional to the beam current are.

If the beam current increases, the alternating current component and also increases vice versa. The winding 11 is only designed so that the alternating current component as Positive coupling to the secondary winding 5 acts. If the direct current increases in the control winding 6 by increasing the beam current in the cathode ray tube 3, then increases again also the alternating current component in the compensation winding 11 and thus acts one Reduction of the heating current in the secondary winding 5 is contrary, because the positive feedback the winding 11 to the winding 5 becomes larger. When the beam current decreases, the opposite effect. Thus remain through this inventive arrangement Voltage and current for the cathode ray tube 3;> onEtant.

Claims (5)

Claims S circuit arrangement for heating a cathode ray tube, preferably a directly heated television picture tube or an oscilloscope tube, its cathode a signal is supplied, characterized in that the heating current for the The transformer supplying the tubes has an iron core, which is preferably designed as a toroidal core which has a narrow B-H area and whose hysteresis curve has a steep one Has a gradient and gradually merges into the saturation area at the top and bottom, this transition not only due to the line deflection current, but also, and although preferably caused by an external field. 2. Circuit arrangement according to claim 1, characterized in that the transformer core designed as a toroidal core is provided with a third winding (6) through which direct current is passed, with which the core is premagnetized in direct current terms and which is dimensioned in magnitude and polarity in such a way that this premagnetization a stable tube heating voltage that is independent of fluctuations in the operating voltage of the device on the secondary winding (5) of the transformer can be removed. 3. Circuit arrangement according to claim 2, characterized in that the third transformer winding (6) in series with the regulating series transistor (T 1) of the stabilized operating voltage power supply (10) of the device. 4. Circuit arrangement according to claim 1 to 3, characterized in that that the transformer core is provided with a fourth winding (? i) with the fluctuations in the secondary winding caused by changing the beam current (5) Removable tube heating voltage can be compensated. 5. Circuit arrangement according to claim 4, characterized in that the fourth transformer winding (11) in series with the choke (L 2) and the collector of the line output transistor (T 2) is placed, so that this winding (i7) a direct current component and a line-frequency alternating current component flow, with these current components are directly proportional to the beam current and the fourth transformer winding (1i) with regard to the number of turns and polarity is designed so that the alternating current component Such positive feedback to the secondary winding (5) causes the fluctuations in the beam current caused residual control errors of the regulating direct currents are compensated.