DE1537311C - Self-oscillating deflection circuit for television receivers - Google Patents

Description

The invention relates to a. Deflection circuit for television receivers with a deflection transformer, its primary winding in series with the collector-emitter path of an output stage transistor on one Operating voltage source is and is coupled to the deflection winding and the one in series with a switching transistor, the base of which is connected to a reference pulse source, on the operating voltage source Has lying feedback winding.

In a known circuit of this type, the switching transistor is in the form of a triggerable breakover diode before, the discharge path parallel to leading from the base of the output stage transistor to ground Capacitors and this discharges during the flyback period and at the same time the base of the output stage transistor short-circuits. The primary winding is located in the collector line of the output stage transistor of a transformer whose secondary winding on the base of this transistor is returned to an energy recovery during the return interval to save the of the deflection circuit to cause the power consumed.

Furthermore, a self-oscillating line deflection stage is known in which the line end tube oscillates as a sine wave oscillator in a basic screen grid circuit. One upstream of the control grid of the output tube Resistance limits the sinusoidal voltage on one side by cutting off the positive half-waves. Because of the relatively large amplitude of the generated Sinusoidal oscillation, the anode current is almost rectangular, but the trailing edges are this The rectangular current is not steep enough to block the tube fast enough. This is why A feedback winding of the flyback transformer is inserted into the control grid circuit of the output tube, which provides additional blanking pulses for faster blocking of the tube. ■ '

The object of the invention is to improve the frequency constancy and the amplitude stability a self-oscillating deflection circuit with energy recovery, as mentioned at the beginning is mentioned. This object is achieved in that the series connection of the switching transistor with the feedback winding is connected to the base of the output stage transistor via a capacitor is.

As a result, the output stage transistor of the circuit according to the invention fulfills two functions, namely he delivers once during the outbound section the deflection period an increasing current to the deflection winding, with its collector voltage is kept constant, on the other hand its collector-base diode acts during the first half of the Trail section of each deflection cycle as a damping diode for the coupling transformer. The inventive Measure leads to a better constancy of the frequency and the amplitude of the generated Sawtooth vibrations.

Further embodiments of the following Hand of the representation of an embodiment explained in more detail emerge from the Subclaims.

In the circuit diagram of the drawing, those stages of the television receiver which feed signals to the display device, for example the picture tube 10, are contained in the block 11 labeled “receiving part”. The receiving part 11 contains the usual devices for the acquisition of video signals (at the output terminal L) for the intensity modulation of the electron beam of the picture tube 10 as well as for the acquisition of the synchronizing pulse information (at the terminals F ₁ and P,) for the synchronization of the windings 14 and 15 of the deflection yoke of the picture tube 10 feeding the line deflection circuit 12 or image deflection circuit 13.

The vertical synchronization pulses pass from the terminal P ₂ to the image deflection circuit 13, which contains an image oscillator stage 16 and an image deflection stage 17. The output terminals V, V of the image deflection stage 17 are connected to the corresponding ends V, V of the vertical deflection winding 15 of the picture tube 10.

The horizontal synchronization pulses pass from the terminal P ₁ to an AFR circuit (automatic frequency control circuit) contained in the dashed block 18. The AFR circuit 18 contains two complementary transistors 19 and 20 which are designed in a feedback circuit. In the input circuits (base-emitter circuits) of the transistors 19 and 20 there is a bias resistor 21 and 22, respectively a capacitor 24, to ground. In a manner still to be explained, line return pulses are coupled to the emitter of transistor 20 via a voltage divider with resistors 25, 26 and a blocking diode 46.

A correction signal, which represents the relative time position of the supplied synchronization and return pulses, is fed from the AFR circuit 18 to a line oscillator 27, which can be designed as a multivibrator, for example. The output oscillation of the line oscillator 27 is coupled to the line deflection and high-voltage generator circuit contained in the dashed block 28. This circuit arrangement 28 contains a control stage 29 and a deflection stage 30. The output terminals H, H 'of the line deflection stage 30 are connected to the corresponding ends H, H' of the horizontal deflection winding 14 of the picture tube 10.

The line deflection stage 30 is designed to be self-oscillating. In fact, there is an operating voltage source, shown as a regulated power supply unit 31, with its pole B - \ - via the primary winding 32 a of a line deflection transformer 32 and a decoupling network, consisting of a resistor 33 and a capacitor 34, with the collector of the line deflection stage 30 (shown as npn transistor) connected. A feedback winding 32 b, which is provided on the transformer 32 to make the deflection stage 30 self-oscillating, is via a circuit with a resistor 35, a diode 36, the winding 32 b and the parallel connection of a capacitor 37 and a resistor 38 to the base -Emitter circuit of deflection transistor 30 coupled. A diode 39 is connected between the base of the deflection transistor 30 and ground with such polarity that it conducts in the direction corresponding to the forward direction of the base-collector junction of the deflection transistor 30. Between the terminal Zf | - and a point in the base-eniitter circuit of the deflection transistor 30, z. IJ. the

connection point of winding 326 and diode 36 a starting resistor 40 is connected.

In order to achieve the high DC operating voltage required for the end anode of the picture tube 10 (e.g. +20,000 Volts) are a high voltage winding 32c and a high voltage rectifier 41 provided.

The horizontal deflection winding 14 is in series with a relatively large capacitor 42 across the output terminals (collector-emitter) of the line sink transistor 30 are coupled. Also is A return capacitor 43 is coupled via these output terminals. It is also about these terminals a voltage clamping or leveling circuit in the form of a diode 44 and a Storage capacitor 45 switched to protect the deflection transistor 30 against strong voltage surges. The voltage developed across capacitor 45 can advantageously be used to generate a to supply the electrodes (grid) of the picture tube 10 with the necessary bias voltage. At the exit (Collector) of the deflection transistor 30 can be a.) Blanking pulse can be picked up.

The return pulses generated at winding 32 b are, as mentioned, fed back via resistors 25 and 26 and diode 46 to AFR circuit 18 in order to synchronize line oscillator 27 with the horizontal synchronization _{pulses taken from terminal P 1.}

When the line deflection circuit 12 is in operation, the line oscillator 27 generates a sequence of square waves, by which the control stage 29 during each of the deflection periods between the conductive and the non-conductive state is switched. And that is in the circuit arrangement shown with a line deflection period of 63.5 microseconds, the oscillator 27 is preferred set up so that it generates periodic waveforms from one at the beginning of the retrace interval positive constant voltage part of about 30 microseconds duration a negative constant voltage part covering the remaining part of the deflection period) closes, insist. The control stage 29 (an npn transistor), to which this oscillation is fed, is thereby in each case switched on to initiate the return and switched off before the middle of the outward flow. When the control transistor 29 is switched on, the deflection transistor 30 is switched off and thereby the Return initiated. When the control transistor 29 is switched off, the deflection transistor 30 is switched off for conditioned the conductive state.

The mode of operation of the self-oscillating deflection stage 30 with the associated circuit elements will now be described. Initially, when the receiver is switched on and the operating voltage Ii I- is supplied, a current flows through the starting resistor 40, the winding 32 ft and the parallel connection of the capacitor 37 and the resistor 38 to the input circuit (base-emitter circuit) of the deflection transistor 30. The capacitor 37 charges during this interval to a voltage of the polarity shown in the drawing. At the same time, the collector of the transistor 30 is supplied with a positive voltage from the terminal Bh via the resistor 33, the capacitor 34 and the winding 32a. The transistor 30 then starts to be routed to, where ¹ he adds the deflection winding 14 and capacitor 42 with a rising current. The windings 32a and 32b have such a mutual phase that as the current conduction in the deflection transistor 30 increases and the voltage on this transistor drops to the saturation level, the voltage on the winding 326 rises and the input circuit of the transistor 30 is thereby supplied with an increasing driver current. The driver circuit is through resistor 35 and the diode

ίο 36, which is polarized so that it provides the required driver current directs, closed.

The oscillator 27 operates at this point in time, and when the oscillator output oscillation changes from the negative to the positive voltage level, the control stage 29 is very quickly controlled into the saturation state (fully switched on). The driver current supplied via the winding 32 b, the resistor 35 and the diode 36 is then transferred from the base-emitter circuit of the deflection transistor 30 to the collector-emitter circuit

so the control transistor 29 switched. At the same time, the Voltage at the capacitor 37 via the control transistor 29 to the input circuit of the deflection transistor 30 coupled in such a polarity that the deflection transistor 30 is blocked. The condenser 37 then discharges through the control transistor 29 and the diode 39. The diode 39 ensures that at the input of the deflection transistor 30 a reverse voltage is maintained, so that the transistor 30 so remains non-conductive for a long time, as the control transistor 29 conducts.

When the deflection transistor 30 is blocked, there is a resonance exchange of the previously in the deflection winding 14 fed energy mainly between the winding 14 and the flyback capacitor 43.

The natural resonance period of these circuit elements is chosen so that approximately half an oscillation period (ie reversal of the current direction in the deflection winding 14) results during the desired retrace interval. While the current in winding 14 passes through approximately half an oscillation period, the voltage between the collector and emitter of deflection transistor 30 undergoes a corresponding oscillation train (ie, a positive return voltage pulse of half-sinusoidal shape is generated). If the voltage at the collector of the deflection transistor 30 exceeds the value of the supply voltage B + , the voltage on the winding 32 b of the transformer 32 has such a polarity that it would cause a current to flow in a direction which is opposite to the direction of the input drive current of the transistor 30 is. However, the polarity of the diode 36 is such that it blocks such reverse current flow. It should also be noted that the diode 36 is polarized in such a way that it blocks the current supplied via the starting resistor 40.

After approximately half an oscillation period between deflection winding 14 and return capacitor 43, the voltage at the collector of deflection transistor 30 is sufficiently negative Value to the collector-base junction of this transistor to tension in the forward direction. Then the return interval ends and the advance begins the next distraction period. The collector-base junction of deflection transistor 30 then acts together with the diode 39 polarized in the same direction as a "damping diode" under manufacture a conduction path for the substantially linearly decreasing current of the deflection winding 14 during

the first half of the outward run. Before the time since the current in the deflection winding 14 reaches zero, the output voltage of the oscillator changes 27 from the positive to the negative value, whereby the .Steuertransistor 29 from the conductive to the non-conductive state is switched. Before inserting the conduction of the deflection transistor 30 in the forward direction becomes the capacitor 37, as in FIG shown in the drawing. Approximately in the middle of the path the deflection period reaches the Current in deflection winding 14 is zero. The one via winding 32ft to the input of the deflection stage 30 zurückgckoppcltc current causes the transistor 30 to be modulated so that it begins conduct in the forward direction. The current in the deflection winding 14, which is now from the deflection transistor 30 is supplied, continues to rise essentially linearly until the oscillator 27 causes the next one Return is initiated.

It should be noted that the supply voltage B + (e.g. IK) OVoIt) is fed to the deflection transistor 30 via the decoupling network 33, 34. The circuit data can be selected in such a way that with zero beam current of the picture tube 10 (ie minimal high voltage load) the voltage at the connection point of the resistor 33 and the capacitor 34 has a value of 1 85 Vc) It. As the beam current increases in the picture tube 10, the additional power (current) required by the deflection and high voltage generating circuit causes the voltage at the junction of resistor 33 and capacitor 34 to drop. As a result, both the high voltage supplied to the picture tube 10 and the deflection current supplied to the deflection winding 14 drop. At the same time, the high voltage can drop further as a result of the load on the high-voltage generator due to the increased beam current. These fluctuations can be regulated in relation to one another in such a way that the image format in the horizontal direction remains constant with changes in the beam current. The decoupling network 33, 34 is dimensioned so that it fulfills this purpose. Furthermore, the image deflection circuit 13 can be fed from the connection point of the resistor 33 and the capacitor 34 in order to keep the vertical image format approximately constant when the beam current (brightness) in the picture tube 10 changes.

In the design of transistorized row numbering acoustics special care must be taken to ensure that the arrangement is correct even under abnormal conditions (/. B. in the event of a flashover in the high-voltage generator circuit) works properly. With the present Circuitry ensure the Pcgcldiodc 44 and the capacitor 45 for protection against Overvoltages at the collector of deflection transistor 30. Capacitor 45 is so in its capacitance large enough so that it absorbs the excessive energy which would be generated in the event of a flashover in the high-voltage generator likely to occur at the collector of the deflection transistor.

The decoupling network 33, 34 provides additional protection for the arrangement. Considering the above-mentioned task of keeping the image format constant in the event of fluctuations in the You can use the resistor 33 and the capacitor 34 mi dimensioned that the deflection transistor 30 is tensioned relatively "softly". That is, one hcmissl the resistor 33 like this.

that the maximum in the line deflection and high voltage generator circuit transferable power is limited to an acceptable value. In addition, the capacitor 34 is dimensioned so small that at high power load (current load) of the source / H- by the line deflection circuit 12 (z. B. during a high voltage flashover) the supply voltage on the capacitor 34 very much drops rapidly. In the event of such a drop in the supply voltage, the feedback effect of the transformer occurs 32 that the control voltage at the input of the deflection transistor 30 drops. This can lead to that transistor 30 turns off (becomes non-conductive), so that excessive power consumption avoided and failure of the deflection stage 30 is prevented. Furthermore, the transistor 30 can Blocked due to a similar feedback effect if the output current (collector current) increases so far that transistor 30 goes out of saturation. ,

A negative supply voltage (of e.g. -5 volts) for other stages of the receiver can, if desired, be provided by connecting a filter network (ftC 'element) between the terminal marked V and ground.

It should now be the mode of operation of the AFR sounding 18, insofar as they relate to the operation of the previously described Parts of the line deflection circuit 12 has influence will be explained. The transistors 19 and 20 are as already mentioned, complementary to one another (i.e. of the opposite conductivity type) and fed back. So when the transistor 19 is supplied with a positive pulse at its base and at the same time the transistor 20 is set to the conduction-ready state

(For example, by applying a positive voltage to its emitter), the transistor 19 supplies a current to the base of the transistor 20, which amplifies this current and returns the amplified current to the base of the transistor 19. By this feedback effect, both transistors 19 and 20 are very quickly driven into the saturation state in which they remain until z. B. the voltage at the emitter of transistor 20 is reversed and thereby the two transistors are blocked. The duration of the transmission state is a measure of the relative phase position of the signals fed to the transistors 19 and 20. In the special circuit design shown in the drawing, the positive line retrace pulses that are developed at the contradiction 35 and the diode 36 are coupled to the emitter of the transistor 20 via the voltage divider 25, 26 and the blocking diode 46. The base of the transistor 19 is supplied with the horizontal synchronization pulses. The two transistors 19 and 20 remain conductive during that part of the flyback interval which follows the occurrence of a synchronization pulse. For example, the synchronization pulse can occur 3 to 4 microseconds after the start of the return and the conduction state of the AFR sound 18 can continue until the end of the return. The line interval is dimensioned with a view to the requirements for the synchronization of the oscillator 27 with the line scanning frequency (15,750 Hz).
The AFR circuit 18 is relatively insensitive to interference, since the gating interval only fills the period between the start of the retrace and the occurrence of the leading edge of the horizontal synchronization pulse {: / .. B. a total of 3 to 4 minutes

microseconds included). When both transistors 19 and 20 are in saturation, have any interference has practically no effect on the output voltage of the AFR circuit 18. Likewise are the effects of vertical compensation pulses as well as the effects of the spikes or Teeth in the vertical pulses (e.g. warping of the upper edge of the image) largely eliminated. RF interference (With compared to the line frequency high frequency) are through the resistor 23 and the Capacitor 24 additionally screened out.

Claims (6)

Patent claims: 1. Deflection circuit for television receivers with a deflection transformer, the primary winding of which is connected in series with the collector-emitter path of a final stage transistor to an operating voltage source and is coupled to the deflection winding and the one in series with a switching transistor, the base of which is connected to a reference pulse source has the feedback winding lying on the operating voltage source, characterized in that the series circuit of the switching transistor (29) with the feedback winding ( 32b) is connected to the base of the output stage transistor (30) via a capacitor (37). 2. deflection circuit according to claim 1, characterized ao characterized in that the series circuit of the switching transistor (29) with the feedback winding (32 b) is connected to the operating voltage source [B +) via a resistor (40). 3. deflection circuit according to claim 1, wherein the base of the output stage transistor via a diode is at a reference voltage, characterized in that the diode (39) in the forward direction the base-collector path of the output transistor (30) is polarized. 4. deflection circuit according to claim 1, characterized in that in parallel with the capacitor (37) a resistor (38) is connected. 5. deflection circuit according to claim 1, characterized in that the primary winding (32 a) of the Deflection transformer (32) connected to the operating voltage source (B + ·) via a resistor (33) and that the connection point of the primary winding (32a) with the resistor (33) is connected to a reference potential via a capacitor (34). 6. deflection circuit according to claim 1, characterized in that the collector of the output stage transistor (30) via the series connection of a diode (44) with a capacitor (45) on one Reference potential is and that the diode (44) is opposite to the forward direction of the collector-emitter path of the end transistor (30) is polarized. 1 sheet of drawings 109 522/152