DE2529361C3 - Picture tube heating for a transistorized television receiver - Google Patents

Description

The present invention relates to the picture tube heater for a transistorized television receiver, especially for color television receivers and / or those with network separation.

State of the art

The German television receivers had an "all-current" power supply from the start because the numerous tubes used, including the picture tube, the series connection of the filaments of the Tubing was the simplest solution. The exception to this was the high-voltage rectifier from the start, whose cathode is fed by the flyback from the flyback transformer by means of a coupling winding became. In Germany, apart from a few exceptions, the installation of a mains transformer always distanced, as this was once too big and heavy, but also the measures for Preventing electromagnetic interference on the receiver circuit and picture tube were too expensive.

With the transistorization of television receivers, the picture tube was the only one left of the tubes of the previous heating chain, so that another source of heating current had to be found. Here z. B. to take the heating current for the picture tube also from the flyback transformer. In addition to this, the individual manufacturers have now also switched to a whole range of other power supply circuits. In addition, with the advent of video recorders and video discs, galvanic separation of the television receiver from the network was desired in order to enable coupling in the video frequency position without a detour via a carrier frequency. In addition, the disconnection from the mains makes it easier to comply with the contact protection regulations of the VDE and to connect headphones, tape recorders, etc. without additional intermediate

to transmitter.

Task and benefits

If the picture tube heater is removed from the flyback transformer, then it drops as a result of the other Functions of this transformer, the value of the winding voltage is relatively high from what to Difficulties in dimensioning the heating winding will result in either this heating winding Fractions of turns or the winding voltage must be lowered, which then the internal resistance of the line step increases and the image width behavior is worsened. There are too series resistors of the picture tube heating coil have already been connected upstream. The present invention continues

2 ^r > now to the task of specifying a solution for the picture tube heating, which avoids these difficulties and allows an optimization of the flyback transformer. In many television receivers, a position shift is required to correct the position of the picture on the screen.

JO practice coil provided. The modification according to the invention This coil for the delivery of the picture tube heating current can be found in the claims.

Description of the invention

J5 The present invention is intended to be based on the in Examples shown in the figures are described in detail. It shows

F i g. 1 shows a section from a known horizontal deflection circuit with means for network separation.

F i g. 2 the removal of the picture tube heating current according to the invention from the picture position shifting coil.
F i g. 3 shows a modification of the circuit according to FIG. 2.
F i g. 4 shows a variant of the circuit according to FIG. 3.
In Fig. 1, FTr denotes the flyback transformer of a known horizontal output stage of a transistorized television receiver, the flyback frequency HLF being applied to the primary winding. The line toggle frequency may be generated in a thyristor stage or else by means of a transistor circuit. from

The two upper windings of the flyback transformer FTr are used to generate high voltage for the picture tube PT, the third as a heating winding for supplying the heating voltage Vpth for the picture tube pT. The fourth supplies the deflection currents for the horizontal deflection coils HDC, with LC means for linearity correction of the line deflection and HCC denoting an image shifting coil. Via the image shift coils HCC, a direct current is applied to the horizontal deflection coils HDL , by means of which the horizontal position of the image on the screen can be adjusted. The lowest secondary winding is used to generate DC supply voltages that are galvanically isolated from the mains.
When realizing such a line transformation

'Λ tors FTr now meet two opposing requirements. On the one hand, the efficiency for the deflection currents supplied to the horizontal deflection coils HDC and for the high-voltage generation

supply optimal, i. be as high as possible. The prerequisite for this is the lowest possible direct current resistance, which not only depends on the cross-section of the wire used, but also on the number of turns result in broken numbers of turns, the realization of which would mean a challenge. In terms of alternating current, the image position shift coil HCC is now parallel to the horizontal deflection coils HDC , into which an additional direct current is fed via the image position shift coil HCC to correct the image position on the screen. So that this cannot flow via the secondary winding of the flyback transformer FTr, the direct current path is blocked via the secondary winding by the capacitor C. So that the horizontal deflection coils HCC are not short-circuited in terms of alternating currents by the image position shift coil HCC , their impedance must be high compared to that of the horizontal deflection coils, which is automatically one low turns voltage of the image position shift coil HCC result

The present invention now uses this to inductively take the heating voltage for the picture tube PT not from the flyback transformer, but from the screen position shift coil HCC , which results in a small winding voltage for the heating winding, i.e. a relatively large and integer number of turns, which is production-wise can be easily implemented

In the F i g. 2 ... 4 this is shown. They show from FIG. 1 only the primary circuit of the flyback transformer FTr and the secondary circuit feeding the horizontal deflection coils HDC. While the heating winding for the picture tube PT on the flyback transformer FTr for F i g. 2 ... 4 is omitted, the remaining secondary windings are retained, but are no longer shown

The image position shift coil HCC receives at the in FIG. The arrangement shown in FIG. 2 has a tap T and is designed as an autotransformer. The transformation ratio and wire size of the two partial windings are selected according to the known rules of transformer calculation so that the desired heating voltage Vpm is generated with good efficiency and both partial windings have integer numbers of turns and the entire face shift coil HCC has such a high impedance that the horizontal deflection coils HDC, which are parallel in alternating current, do not to be influenced.

ίο In Fig.3 a modification of this circuit is now shown The picture position shift coil is here supplemented by a secondary winding SWt to a transformer. This secondary winding now supplies the heating current for the picture tube pT and at the same time also the direct current for the picture position shift. For this purpose, the AC voltage present at the secondary winding 5IVl is rectified, which is shown in the drawing by a rectifier and charging capacitor.

2üung one above the loading block and thus above the so obtained DC voltage lying potentiometer is connected to ground, so that on the potentiometer positive and negative voltages can be tapped with respect to ground and the desired

2nd image position shift current can be set. The heating voltage Vpth required for the picture tube PT can, as shown in FIG. 3, be taken from the terminals of the charging capacitor as direct current or as alternating current from the secondary winding SWi

jo men. The expediency of this arrangement is determined by the level of the heating voltage Vpth required for the picture tube PT and the voltage range required for shifting the picture position
If the two values differ from one another, F i g shows. 4th

appropriate for this case variant of the circuit of FIG. 3. There are now two secondary windings SWl and provided SW2, wherein by means of the secondary winding SWi is available by rectifying means of the lying at a tap to ground potentiometer of the voltage range required for the image position shift while the Secondary winding SW2 is designed so that the required heating voltage Vpth for the picture tube PTH can be taken from it.

1 sheet of drawings

Claims (4)

Patent claims: 1. Picture tube heating for a transistorized television receiver, in particular for a color television receiver, in which the heating of the cathode of the television picture tube, the return pulses of the line frequency are used and a picture position shift coil is provided to correct the picture position on the screen, characterized in that the heating voltage (Vpth) for the picture tube (PT ) is inductively decoupled from the picture position shifting coil (HCC) which is used to correct the picture position on the screen. 2. Picture tube heater according to claim 1, characterized in that the heating voltage (Vpth) for the picture tube (PT) is taken from the picture position shift coil (HCC) expanded by a tap (T) to an autotransformer (HCTr) . 3. Picture tube heater according to claim 1, characterized in that the picture position shift coil (HCC) is expanded by applying a secondary winding (SWi) to the transformer (HCTr) , that this secondary winding (SWl) the heating voltage (Vpth) for the picture tube (PT) and after Rectification also the correction current for the horizontal deflection coils (HDC) is taken. 4. Picture tube heater according to claim 3, characterized in that a further secondary winding (SW2) is applied to the picture position shifting coil (HCC) and that the heating voltage (Vpth) of the picture tube (PT) is taken from this further secondary winding, during the first secondary winding (SWl) furthermore, after rectification, the correction current for the horizontal deflection coils (HDC) is taken.