DE2720086B2 - East-west pillow correction circuit for color televisions - Google Patents

Description

The invention relates to an east-west pillow correction circuit for color televisions with a diode modulator on the secondary side of the horizontal deflection transformer is arranged.

An east-west pillow correction circuit of this type is in DT-PS 20 31 218 and in the development-technical notices of the Valvo company in issue no. 53, Pages 20 to 23.

Such an east-west pillow correction circuit (hereinafter also referred to as OW pillow correction) with a diode modulator does not affect the flyback pulse voltage at the horizontal transformer and is also characterized by an internal cushion-free rectification of the image raster in the horizontal direction.

The disadvantage of the circuit is based on the fact that the inevitably generated by the diode modulator DC voltage must be loaded with a minimum current. If the load falls below the minimum current, so the modulator voltage rises sharply. The minimum load current can shift to low values when the control circuit for the modulator is blocked. A drop in load current below these However, a new minimum limit current then leads to a voltage increase again.

It is known, with the necessary load current circuit groups of the television, such. B. Vertical deflection amplifier, To operate IF amplifiers, video amplifiers, chrominance amplifiers, etc. A break the power supply to individual circuit groups can be used in the event of a fault or if it is off Plug-in sockets pulled out circuit groups cannot be excluded. For those in the chassis remaining circuit groups then there is a risk of voltage overload if the lowest The modulator voltage falls below the minimum load current.

The circuit groups often require a lower operating voltage than the modulator voltage im Normal operation supplies. Here must then be a loss-prone Adjustment can be made.

These disadvantages mentioned above can be avoided with a known diode modulator, the is arranged directly on the primary side of the horizontal transformer Mcdulator voltage is also the operating voltage a separate load current is not necessary. However, high blocking modulator diodes are required for this can be used, as well as a transformer to match the control circuit. These components are

ι υ expensive and, in the case of diodes, also critical with respect to the service life.

The object of the invention is now to use the advantages of the secondary diode modulator with its inexpensive and non-critical components and the advantages of the primary diode modulator with its dead load behavior to unite.

This object is achieved according to the invention by the invention specified in claim 1. Through this the horizontal deflection stage itself acts as the most important load on the diode modulator. In the event of an exposure the H-deflection stage no modulator voltage is generated and it is therefore compared to the previously usual Secondary modulator circuit, a voltage increase in the event of a fault is impossible.

Further circuit groups can be operated safely from the modulator voltage.

Other advantages of the invention consist in the low power consumption of the invention operated televisions. In addition, there is less heating in the device. This allows smaller heat sinks are used and savings are made in the power supply unit.

Embodiments of the horizontal deflection circuit and the diode modulator are shown in the drawings

J5 and described in more detail below. It shows F i g. 1 shows a known horizontal deflection and diode modulator circuit compared to the in

F i g. 2 shown horizontal deflection and diode modulator circuit according to the invention.

In FIG. 1 shows the operating voltage supply for the horizontal deflection stage and the diode modulator. The mains voltage is applied to terminals A and B. The operating voltage is processed in circuit group 1, e.g. B. by a switched power supply according to the flyback converter principle and is output to terminals C and D.

The horizontal deflection stage with the terminals G and H consists of the primary winding 2 of the horizontal deflection transformer 19, the bipolar one

M switching stage 4, 3, the return tuning capacitor 5, the S-correction or tangent equalizer capacitor 6, the horizontal deflection winding 7 and the bridge coil 8. The operating voltage is connected to the deflection stage via the terminals Can G and Dan H.

A control signal with the horizontal deflection frequency is applied to terminals K and L , in accordance with the television picture standard received. The controlled switching stage 4, 3 produces an almost sawtooth-shaped deflection current in the deflection winding 7, which deflects the electron beam in the picture tube in the horizontal direction. A second deflection device (not shown in the figure) deflects the electron beam in the vertical direction, so that the electron beam, starting from the upper edge of the image, is guided line by line to the lower edge of the image. Since the distance between the starting point of the deflection and the screen surface is different, the result is a pillow-shaped distortion of a rectangular grid on the screen. This pillow-shaped distortion

tion is eliminated by an OW correction circuit, which generates a horizontal deflection current of different sizes depending on the vertical deflection of the electron beam. The diode modulator, which consists of the secondary winding 9 of the horizontal deflection transformer 19, the diodes U and 12, the tuning capacitor 10, the filter capacitor 13, the OW control coil 15, the coupling and S correction capacitor 14 and the OW control circuit 16, is used for this purpose the inductance ratio of _{the! 0} deflection coil 7 to the bridge coil 8 is located at the junction of these coils, a part of the deflection voltage, which is dimensioned such that when short-circuited bridge coil 8 of the deflection current in said deflection winding 7 increases by as much as the maximum is OW correction necessary is.

The voltage at the secondary winding 9 of the horizontal deflection transformer 19 is the same as at the connection point of the coils 7/8. The filter capacitor 13 is charged by rectification via the diodes 11 and 12 during the trace. An equally large DC voltage potential arises at the coupling or S-correction capacitor 14 through the diode path via the diode 12. If no current is discharged via the connection M , the bridge AC voltage at the connection point 7/8 to the diode 11/12 is the same and the deflection current in the coil 7 flows only via the coil 8 In contrast to this, a deflection current flows as a permanent charging current via the coupling capacitor 14 and the diodes 11, 12 when a direct current is discharged from the coupling capacitor 14 3 ″ via the OW control coil 15. The alternating deflection current thus now flows via the significantly lower impedance of the coupling capacitor 14, which leads to a higher deflection current in the coil 7. With the capacitor

10, the detuning of the sinusoidal half-oscillation during the return movement, which is caused by the change in impedance at the connection point 7/8, is compensated. The high-voltage winding 17 of the horizontal deflection transformer 19 is thus free of amplitude changes caused by the OW modulator. The rectifier 18 is used to generate the high voltage of the picture tube. The OW control circuit 16 takes a vertical-frequency parabolic current from the terminal M , which is dimensioned such that the horizontal deflection amplitude results in straight lines at the left and right edges of the image in the vertical direction.

The part of the charging current of the coupling capacitor 14, which in the first half of the trace over the diode

11 flows to the filter capacitor 13, must be dissipated by a load current (terminal E to F). If this does not happen, the voltage between terminals E and F rises sharply. The load current can be used to supply circuit groups. A circuit group 20 shows this as an example, the resistor 21 serving to reduce the voltage.

In Fig. 2 shows a circuit according to the invention. The with the in F i g. 1 circuit shown Matching circuit parts are provided with the same reference numerals so that they are not repeated need to be explained.

The circuit according to the invention according to FIG. 2 differs from the circuit according to FIG. 1 by the operating voltage supply of the horizontal deflection circuit. The operating voltage for the horizontal deflection rod results from the circuit connection of the supply voltage with the diode modulator voltage. The connection D of the power supply circuit 1 is connected to the terminal £ of the modulator voltage and the horizontal deflection stage with the terminals G and H is connected to the external connection points C and F of this series circuit. This results in a load on the diode modulator voltage in the amount of the power consumption of the horizontal deflection stage. If the deflection stage is put out of operation due to an error and fails to consume electricity, there is also no modulator voltage. Complete self-protection against modulator overvoltages is thus achieved

In the event of a short circuit in switching stage 4, current flows from terminal C of the operating voltage supply to terminal C via winding 2, switching stage 4 to terminal H / F, via diodes 12 and 11, winding 9 to terminal E / D in the power supply unit 1 back. The modulator voltage (connection E, F) is reversed in polarity with respect to the normal voltage and limited to the forward voltage of the diodes 11 and 12. Damage to the assemblies 16 and 20 must be ruled out.

Which terminal of the diode modulator voltage is connected to the common chassis ground is irrelevant for the operation of the circuit.

If the terminal E is connected to the ground connection of the chassis, a negative modulator voltage results, and if the terminal Fan is connected, the chassis results in a positive modulator voltage.

Reference symbols used

B, C, D, 12th German A, F, K, L Clamps E. H Clamps G, Terminal of the horizontal distraction level M. Connection 1 Power supply unit, Circuit group 2 Primary winding of the horizontal % deflection transformer 19 3, - bipolar switching stage 5 Return tuning capacitor 6th S-correction capacitor 7th Horizontal deflection winding 8th Bridge coil 9 Secondary winding of the hori zontal converting transformers 19 10 Tuning capacitor 11 Diodes 13th Filter capacitor 14th S-correction capacitor, Coupling capacitor 15th OW control coil 16 OW control circuit 17th High voltage winding 18th Rectifier 19th Horizontal deflection transformer 20th Circuit group l \ resistance

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. East-west pillow correction circuit for color televisions with a diode modulator which is arranged on the secondary side of the horizontal deflection transformer, characterized in that the power pack supply voltage (1) with the terminals (C and D) with the voltage generated by the diode modulator (terminal E, F ) is connected in series and the horizontal deflection stage (terminal G, H) is connected to the two outer connection points (QF) of this series circuit 2. east-west cushion correction circuit according to claim 1, characterized in that the negative terminal (F) of the diode modulator voltage is connected to the common ground connection of the chassis 3. east-west cushion correction circuit according to claim 1, characterized in that the positive terminal (E) of the diode modulator voltage is connected to the common ground connection of the chassis.