FI75246C - KOPPLINGSREGULATOR FOER TELEVISIONSANORDNING. - Google Patents

Description

ITYJA ^ TI NOTICE n c n,, [B] (11) UTLÄQQNINGSSKRIFT / 0Z4Ö (45) ^ '* - - n (51) KvIk.VlntCl4 H OA N 3/18

SUOMI FINLAND

(Fl) (21) Patent application - Patentansökning 792717 (22) Application date - Ansökningsdag 3 1. 08.79

National Board of Patents and Registration (23) Start date-Giitighetsdag 31.08.79

Patent- och registerstyrelsen (41, Become public, _Bljvit offentltg 08. '03.80 (44) Date of publication and six months of publication -

Ansökan utlagd och utl.skriften publicerad 29.01 .oo (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed - Begärd priority 07.09 * 78 02.11.78 USA 9 ^ 0286, 957221 (71) RCA Corporation, 30 Rockefeller Plaza, New York, New York, USA (72) Donald Henry Willis, Indianapolis, Indiana,

The present invention relates to a switching controller comprising an adjustable thyristor switch, a storage inductor, a commutation winding, and to the following: The present invention relates to a switching controller comprising an adjustable thyristor switch, a storage inductor, a commutation winding. , a horizontal deflection generator including a high voltage generator as a load on the picture tube, said elements forming a circuit connected to a source of unregulated DC voltage to provide a current path to the increasing current of the storage inductor to the horizontal transformer, in order to control the moment when said switch becomes non-conductive, the switching controller further comprising a storage capacitor connected to the switching controller and the deflection generator stores to filter the operating voltage for the deflection generator, a control circuit connected to the deflection generator and replacing the thyristor switch to control the moment when the thyristor switch becomes conductive, to control the average of the increasing and decreasing currents of the inductor and to control said operating voltage.

In order to avoid the additional weight and cost of a mains isolation transformer, power may be supplied to the televisions directly from the AC mains via a rectifier and a filter. The filtered DC voltage varies in proportion to the AC mains voltage fluctuations, which can be detrimental. Likewise, the value of the filtered DC voltage is approximately the peak value of the AC input and may be greater or less than what is the desired value.

It is possible to provide a regulated output voltage with a smaller magnitude than with an untreated DC input using a series-type control circuit, but this has the disadvantage of substantial power loss when the load current and / or the difference between the supply voltage and the regulated voltage is large.

The recent effort to reduce power consumption has led to an increasing use of switching controllers to supply power to television receivers. In switching controllers, a switch connected to the supply of unprocessed DC voltage is periodically switched on and off when this operating cycle is suitable for regulating the set voltage. U.S. Patent 4,024,434, issued May 17, 1977 to Joosten, illustrates the use of a transistor used as a switch to reduce power loss. Although power loss is reduced in this type of operation, transistors often have a low amplifier factor and require a substantial supply to the base in order to operate in a low power saturated mode. Furthermore, the inductance, which is often associated with a switching controller, requires a so-called a free-operating diode to prevent excessive voltages being applied to this transistor during its shutdown and to recover energy stored in this inductance.

The use of controlled rectifiers, such as SCR silicon rectifiers, eliminates the base control problem associated with using a transistor as a switch. That SCR is regenerative and when it is gated into the conductivity state, it remains conductive as long as the line bias voltage is maintained over its main current conductivity paths. Thus, the gating pulse can be momentarily applied to the SCR control electrode to initiate its conductivity and thereafter no longer need to be applied to maintain conductivity. The regulated rectifier switch is turned off when the line current decreases to zero and tends to reverse, which is normally caused by applying the opposite voltage to it from an external supply source. This SCR is advantageous when compared to a transistor, not only because of its gating characteristics but also because the introduction of an opposite voltage exceeding the breakdown value of the blocking voltage of this element does not lead to its destruction but only to its switching to a conductive mode.

U.S. Patent 3,970,780, issued July 20, 1976 to Minoura, describes a switching controller that uses an SCR rectifier as a control element to charge a capacitor from an unregulated supply source through a series circuit having an inductance and a winding connected to a horizontal deflection circuit. In this Minoura arrangement, the inductance must be small enough so that the current in the inductance and the SCR rectifier can be reduced to zero during the return interval using the difference between the unregulated DC voltage across the winding and the extinguishing voltage pulse. As a result, relatively large peak currents flow in the inductance and storage capacitor during the capacitor charge interval. These relatively large currents adversely lead to a relatively large I R value, i.e. heat losses. Likewise, the shutdown requirements and relatively large changes in controller current that occur with changes in load current, such as those resulting from changes in the amount of beam current in the picture tube, cause large changes in the peak currents of the controller. These changes in the peak current flowing through the SCR portion of the controller and through the cut-off windings result in changes in the amount of energy connected between the deviation circuit winding and the horizontal output transistor and contribute to return time modulation and storage time modulation with the output transistor. Modulation of the storage time causes the vertical lines shown on the raster to bend. It is desirable to reduce the return time modulation and deflections resulting from beam current changes to reduce peak currents and heat loss and to reduce load-dependent variations in the voltage pulse available to the quench controller SCR to use a higher filter inductance.

The switching controller according to the present invention is characterized in that it has a combination in which a diode is connected to the output of a thyristor switch in a manner known per se and which assists the commutation voltage generated by horizontal beam pulses. non-conductive before any significant decrease in current in the storage inductor.

In the accompanying drawings, Figures 1-4 are diagrams in block and circuit diagram form in a portion of a television display apparatus incorporating the invention; Figures 5 and 6 illustrate amplitude-time waveforms for certain periodic voltages and currents present in the apparatus of Figures 1-4 during operation; Fig. 7 illustrates another embodiment of an apparatus according to the present invention in the form of a block and circuit diagram; Fig. 8 illustrates an apparatus similar to Fig. 7; Fig. 9 illustrates a voltage-time waveform for return pulses present in the apparatus of Fig. 8 during its operation.

In Figure 1, supply terminals 10 and 12 are suitable for connection to an unregulated DC voltage supply source, such as a rectified and filtered mains voltage. The anode-cathode current path, filter inductance 16, and horizontal deflection circuit 22 of the SCR rectifier 14 are connected together to the circuit points 26 and 30, respectively, to form a certain first series-connected circuit. This series-connected circuit is connected across the supply terminals 10 and 12 by a secondary winding 20b of the transformer 20. The storage capacitor 18 is connected between the circuit point 30 and the supply terminal 12. The deflection circuit 22 is powered by a voltage across this capacitor. The anode of the diode 24 is connected to the switch terminal 12, which will then be called "ground", and its cathode is connected at the circuit point 26 to the switch terminal of the inductance 16 to form a closed second series current path, i.e. a circuit for current through the inductor 16, capacitor 18 and diode 24 .

The voltage control circuit illustrated in block 36 is connected to ground and to a circuit point 30 by a conductor 28. The voltage control circuit 36 may be of the type known per se in the art and is disclosed, for example, in the aforementioned U.S. Patent 3,970,780. The voltage control circuit 36 detects the voltage between point 30 and ground and provides periodic gating pulses which are coupled via transformer 32 to the control gate of SCR rectifier 14 to maintain the voltage at point 30 substantially constant relative to ground. The conductor 34 connects the horizontal deflection circuit 22 to the voltage control circuit 36 in order to synchronize the periodic gate pulses with the horizontal deflection in a known manner. The primary winding 20a of the transformer 20 is connected to the horizontal deflection circuit 22 to connect the return voltage pulses from the horizontal deflection circuit to the anode-cathode main current path of the SCR rectifier 14 by a disconnecting secondary winding 20b to periodically open or cause the SCR 14 to be de-energized.

During operation, the voltage control circuit 36 provides SCR gating pulses, illustrated as V36 in Figure 5a, which are provided in a timed relationship with the recovery voltage pulses illustrated as V20a in 5b and provided by the horizontal deflection circuit 20 primary. Immediately before the time TO, as illustrated in Fig. 5, the voltage provided by the winding 20b is small and the SCR 14 is conductive, thus making the voltage between the circuit point 26 and the switch terminal 12 positive; as illustrated by Form V26 in Figure 5c, and this provides a blocking bias to diode 24. When SCR 14 is conductive, an unregulated voltage is applied across the series connection of winding 20b, inductance 16, and horizontal deflection circuit 22, resulting in increased current in inductance 16 and is illustrated by Form 116 in Figure 5d and Form I20b in Figure 5e. This current charges the capacitor 18 and also supplies the need for a horizontal deflection circuit 22. Charging the capacitor 18 causes the voltage at point 30 to increase slightly.

At time TO, the deflection circuit 22 starts a return pulse. As the return voltage increases, the voltage at the anode 14 of the SCR becomes increasingly negative. The energy associated with the magnetic field of the inductance 16 causes the current to continue to flow through the SCR 14 until time T1, when the anode of the SCR 14 is substantially at ground potential and the circuit point 26 is negative to ground due to the conductive voltage drop of this SCR. . At this point in time, the diode 24 receives current from the SCR 14. The subsequent increase in the magnitude of the return voltage pulse generates a reverse bias to the SCR 14 and renders it non-conductive.

In the interval after time T1, the SCR 14 is non-conductive and some of the energy associated with the magnetic field of the inductor 16 is transferred to the capacitor 18 as the current circulating through the second series path decreases, so the series includes the inductor 16, the capacitor 18 and the diode 24. 5f. At a later time, the return time interval T2 ends and the SCR 14 once again becomes biased in the line direction. However, the SCR 14 does not conduct until at a certain later time T3, when the gating pulse is applied to the gate of the SCR to make it conductive. At time T3, the voltage at point 26 increases substantially to the sum of the unregulated DC voltage and the voltage across the winding 20b. Diode 24 receives a bias bias and is therefore non-conductive, and the inductance current 116 begins to increase again, continuing to transfer charge to capacitor 18 and deflection circuit 22 as energy is once again stored in inductor 16.

As described, the current of the inductance 16 decreases from a certain point in time near the beginning of the return interval until time T3, when the gate SCR 14 is controlled to conduct. At time T3, the current at inductance 16 stops decreasing and begins to increase again. The current is filtered by a capacitor 18 which generates an operating voltage for the deflection circuit 22. The operating voltage is regulated based on the setting of time T3. Thus, if the regulated voltage at the switch terminal 30 relative to ground tends to fall below a certain desired value, the control circuit 36 provides a gating pulse V36 earlier during the deflection period, as illustrated at time T3 'in Fig. 5 As shown by dashed lines in Figs. 5c-5d, an earlier gating pulse such a net increase may maintain a controlled voltage at point 30 during the increased current demand of the deflection circuit 22 or may compensate for a tendency to low weather 75246 7 regulated voltage caused by a low unregulated voltage value or some other reason.

As described, the operation of the arrangement of Figure 1 is suitable when the inductance 16 is relatively small. For smaller inductance values of the inductance 16, the current in the winding can be reduced to zero before the time T3, when the SCR is turned on, in which case the voltage V26 at the circuit point 26 rises to the regulated voltage when the current in the inductance 16 and diode 24 ceases.

Although the above description describes a capacitor 18 connected between a regulated voltage switch terminal 30 and ground, a capacitor 18 may be connected between a circuit point 30 and another reference voltage point. Fig. 2 illustrates an arrangement similar to Fig. 1 with a different reference point for the storage capacitor 18, and also illustrates the series connection of the winding 20b and the SCR rectifier 14. In Fig. 2, parts corresponding to those in Fig. 1 are denoted by the same reference numerals using a series of numbers 200. In Fig. 2, the switching terminals 210 and 212 are suitable for connection to an unregulated DC voltage supply source. An adjustable switch in the form of an SCR 214, the main current conduction path from the circuit points 226 and 230 is connected in series with the filter inductance 216 and the horizontal deflection circuit 222, and this series combination is connected over the switch terminals of the unregulated supply source. The storage capacitor 218 is connected between the circuit point 230 and the switch terminal 210. From the diode 224, its anode is connected to the supply source switch terminal 212 and its cathode is connected to the inductance 216 at the circuit point 226 to form a series with the inductance 216 and capacitor 218 where current may flow along a closed current path. The voltage control circuit 236 is connected to the switch terminal 212 and the circuit point 230 to detect the voltage across the horizontal deflection circuit 222 and is also connected by a transformer 232 to the gate of the SCR 214 to control the switching of the SCR portion to keep the voltage across the deflection circuit substantially constant. The voltage control circuit 236 is also connected to the deflection circuit 222 by a conductor 234 to synchronize the connection of the SCR section 214 with the deflection period. The transformer quenching winding 220b is connected between 824246 circuit point 226 and SCR 214 cathode. The winding 220a of the transformer 220 is connected to the horizontal deflection circuit 222. The transformer 220 connects the return pulses provided by the horizontal deflection circuit 222 to the SCR 214 to periodically make this SCR non-conductive. For purposes of explanation, switch terminal 212 will hereinafter be referred to as "ground."

The operation of the arrangement of Figure 2 differs from the operation of the arrangement of Figure 1 in that the flow of current in the load represented by the horizontal deflection circuit 222 causes current to flow in the capacitor 218, which tends to charge this capacitor, i.e. tends to increase the voltage across the plates. Because the unregulated DC voltage changes relatively slowly relative to the deflection frequency, the voltage between the switch terminals 210 and ground can be assumed to be constant from line to line. As the capacitor 218 charges, the voltage at the circuit point 230 decreases with respect to ground. Thus, just like in Figure 1, the flow of the load current tends to cause a decrease in this load voltage.

In order to increase the voltage across the horizontal deflection circuit in the arrangement of Figure 2, capacitor 218 must be discharged. This is accomplished when the SCR 214 is conductive through a first series-connected current path from the capacitor 218 to the SCR 214, the winding 220b, and the inductance 216 back to the capacitor. During the time that the SCR 214 is conductive, current is also applied through the SCR 214 and the inductance 216 to the deflection circuit 222. When the SCR 214 is de-conducted by a return pulse supplied from the winding 220b, the energy stored in the magnetic field associated with the inductance 216 is used. continue to supply current to the deflection circuit 222 and discharge the capacitor 218 via a second series current path from the inductance 216 to the circuit point 230, the capacitor 218, the unregulated voltage supply source, and the diode 224 back to the inductance 216.

The detailed operation of the arrangement of Fig. 2 can be explained with reference to Fig. 5. Immediately before time TO, when the return voltage pulse is generated by deflection circuit 222, SCR 214 is conductive and the voltage at circuit point 226 is substantially equal to the sum of unregulated voltage and winding 220b. illustrated at V226 in Figure 5c. The current of inductance 216 increases, as illustrated at 1216 in Figure 5d, under the influence of the voltage across capacitor 218. At this stage, the current of the inductance 216 also passes through the winding 220b, as illustrated in Figure 5e. At time TO, the return pulse V220a is applied to the primary winding of the transformer 220 and a pulse voltage is applied between the circuit point 226 and the cathode of the SCR 214, the polarity of which is connected to make the silicon point 226 negative and the cathode of the SCR section 214 positive.

As long as the SCR 214 is conductive, its cathode is at the level of a substantially unregulated DC voltage, and as a result, the circuit point 226 is increasingly forced negative as the return voltage increases. At time T1, when the voltage pulse across the winding 220b is substantially equal to the unregulated DC voltage, the circuit point 226 becomes negative by Vbe compared to ground and the diode 224 becomes conductive. Further increases in the pulse voltage across the winding 220b cannot make the circuit point 226 more negative, and as a result, the cathode of the SCR section 214 becomes more positive than the switch terminal 210 and the SCR becomes non-conductive.

When the SCR 214 becomes non-conductive at time T1, current continues to flow through the inductance 216 to the circuit point 230 and through the capacitor 218, but instead returns through the SCR 214, it passes as described from the unregulated supply source switch terminal 210 to the switch terminal 212 and returns to the inductance 216. 224 through. Part of the current from inductance 216 also passes through circuit point 230 to deflection circuit 222 and is returned through diode 224. Some of the energy stored in the magnetic field associated with the inductance 216 is returned to the beam unregulated supply source and part of it is applied to the deflection circuit 222. At time T2, the return interval ends and the SCR 214 regains the bias, but remains unconducted T the gating pulse V236 is generated by the voltage control circuit 236, as illustrated in Figure 5a. At time T3, the SCR 214 becomes conductive and the voltage at the circuit point 226 rises, which once again causes the current of the diode 224 to be non-conductive. Inductance 216 is connected by SCR 214 across capacitor 218 and capacitor 218 begins to discharge, transferring energy stored as voltage across its plates to inductance 216 along a series-connected path that includes SCR 214, as described. This results in an increase in the current in the SCR section 216, as illustrated in Figure 5d.

The voltage at the circuit point 230 in Fig. 2 is controlled by changing the average current of the inductance 216, which is determined from the time T3 during the deflection period, during which the gate SCR 214 is controlled to conduct. Thus, if the regulated voltage at the switching terminal 230 tends to decrease below the desired value relative to ground, the control circuit 236 provides a gating pulse V236 earlier during the deflection period, as illustrated at time T3 'in Fig. 5. As shown by the dashed lines in Figures 2c-2e, 216 in the average current 1216, which is capable of discharging capacitor 218 to a greater extent to maintain a regulated voltage in the presence of increased current consumption of the deflection circuit 222 or to compensate for a low controlled voltage. As in the case of Figure 1, the operation is described for the situation where the inductance 216 has a relatively large inductance. In the case of a lower inductance, the current in the inductance 216 may decrease to zero before the time T3, after which the diode 224 becomes non-conductive and the silicon point 226 reaches the level of the regulated voltage.

In the embodiments of Figures 1 and 2, the extinguishing or secondary winding is connected in series with the SCR part. It is possible to arrange the quenching or secondary winding in series with the diode, as illustrated in Fig. 3. In Fig. 3, the parts corresponding to the parts in Fig. 1 are denoted by the same reference numerals 300. In Fig. 3, switching terminals 310 and 312 are suitable for switching to an unregulated DC supply. The SCR 314, which acts as an adjustable switch, is connected from circuit point 326 to filter inductance 316, which in turn is connected at circuit point 330 to deflection circuit 322, and this series combination is connected across switch terminals 310 and 312 to form a first series path for inductance 316. Capacitor 318 is connected between circuit point 330 and switch terminal 312 to filter the current flowing in ιι 75246 at inductance 316 to provide an operating voltage for deflection circuit 322. From the diode 324, its cathode is connected to the circuit point 326 and its anode is connected to the terminal 312 by a secondary winding 320b of the transformer 320 to form a closed current path through the inductance 316, capacitor 318, winding 320b and diode 324 back to the inductance 316. connected to a horizontal deflection circuit 322. A voltage control circuit 336 is connected by a conductor 328 over a capacitor 318 to detect the voltage to be adjusted, and is also connected by a conductor 334 to a horizontal deflection circuit to provide synchronization pulses therefrom. The voltage control circuit 336 provides time-modulated SCR control pulses which are connected to the gate of the SCR section 314 by a transformer 332.

Referring now to the waveforms in Figure 6, immediately before the time TO, when the return time interval begins, the SCR 314 is conductive and the circuit point 326 is at a voltage of a substantially unregulated supply source, as illustrated in Figure 6c. Diode 324 is non-conductive and its anode is at a voltage that is negative to ground by the voltage across winding 320b, as illustrated in case V301 in Figure 6b. The current through inductance 316 increases in the current path starting from switch terminal 310 at the unregulated supply source, passing through SCR 314 and inductance 316, as illustrated in 1316 in Figure 6d, under the influence of the voltage difference between circuit points 326 and 330. A portion of this current is supplied to the horizontal deflection circuit 322 and the remainder charges the capacitor 318.

At time TO, the deflection circuit 322 provides a return voltage pulse which is connected to the secondary winding 320b of the transformer 320. The polarity of this voltage is set to make the point 301 of the circuit more positive with respect to ground. Diode 324 remains non-conductive until the voltage at point 301 rises at time T1 to 1 V ^ e above the voltage at circuit point 326.

At time T1, diode 324 and winding 320b provide an alternative current path for current flow through inductance 316. After time T1, the return voltage pulse further causes an increase in voltage at both circuit points 301 and 326, and SCR 314 then becomes non-conductive. At a later time, the return pulse voltage at the circuit point α2 75246 at 301 reaches a peak value and begins to decrease. After the pulse 301 decreases below the controlled B + value, the decreasing current continues to flow through the inductance 316 along a circular path including a capacitor 318, a winding 320b, and a diode 324, as the energy associated with the magnetic field of the inductor 316 continues to pass to the capacitor 318. the decreasing voltage at circuit points 301 and 326 again causes the SCR 314 to be biased in the directional direction. However, the SCR 314 does not become conductive until a gating pulse is applied to it.

The return pulse ends at time T3 and the current continues to circulate through inductance 316, capacitor 318, and diode 324, as illustrated at 1316 in Figure 6d. At time T4, the voltage control circuit controls the gate of the SCR 314, which increases the voltage at the circuit point 326 and renders the diode 324 non-conductive, thus initiating an increase in the current of the inductance 316 at time intervals. As in the case of Figures 1 and 2, a controlled voltage is maintained between circuit point 330 and ground by adjusting the average value of current 1316, which in turn is determined by the relative gate switching time T4 at which the SCR 314 is energized.

Fig. 4 illustrates an embodiment of the present invention similar to Fig. 3 in that the disconnecting winding and the diode are connected in series. The arrangement of Figure 4 differs from the previous one in that the storage capacitor has a different reference point and that the SCR is connected to the negative terminal of the unregulated voltage supply source.

In Figure 4, switch terminals 410 and 412 are suitable for connection to an unregulated DC voltage supply source. The cathode of SCR 414 is connected to switch terminal 412 and the anode is connected to switch terminal 410 via circuit point 426, filter inductance 416, ground, and horizontal deflection circuit 422. The ground point corresponds to circuit point 30 in Figure 1. The storage capacitor 220 voltage. The anode of diode 424 is connected to circuit point 426 and the cathode is connected to the positive switch terminal 410 of the unregulated voltage supply source by the secondary winding 420b of the transformer 420. The horizontal deflection circuit 422 generates return pulses which are connected to the winding 420b. The voltage control circuit 436 is connected via a conductor 428 across the horizontal deflection circuit 138 to measure the operating voltage of the horizontal deflection circuit between the switch 410 and ground and to provide the control pulses connected to the gate of the SCR 414 via the transformer 432.

The voltage across the horizontal deflection circuit 422 is equal to the difference between the unregulated supply voltage and the voltage across the capacitor 418. The flow of current in the deflection circuit 422 as a result of this operation causes a charge to accumulate in the capacitor 418 during the time intervals when the SCR 414 is non-conductive, thus increasing the voltage across the capacitor and tending to reduce the voltage available to the deflection circuit 422. The regulated voltage is controlled by discharging the capacitor 418 starting from the capacitor through the inductance 416 to the circuit point 426, the SCR 414 and back to the capacitor, and when the SCR is non-conductive via an alternative path from the capacitor 418 through the inductance 416 to the circuit point 426, the diode 424, the winding 420b and the switching terminal 410 through the capacitor switch terminal 412.

The waveforms of Figure 6 are similar in appearance to the waveforms present in the arrangement of Figure 4 during operation, but differ from these in polarity and by a fixed offset voltage as a result of a different voltage reference point. Immediately before the moment TO at the start of the return interval, the SCR 414 conducts and the diode 424 is non-conductive. The current through the inductor 416 increases under the influence of the voltage in the capacitor 418 as energy is transferred from the capacitor 418 to the inductor 416. During the return interval, the winding 420b generates a pulse voltage at the diode 424 cathode, which is increasingly negative. 424 cathode approximately 1 V negative at circuit 426, SCR 414 becomes non-conductive and diode 424 becomes conductive, providing a reduced current flow through an alternative series path including diode 424, winding 420b, unregulated supply source, capacitor winding, capacitor 418 and inductor 416. 420b is small and the current continues to flow through diode 424 and an alternative series path. As a result, the circuit point 426 is at 2 4 75246 at a voltage close to the corresponding value at the switch terminal 410, and the SCR 414 receives a line bias voltage. During the time interval from the end of the return interval to the time the SCR 414 is made conductive, the inductance 416 is substantially connected across the unregulated supply source and the current at the inductance 416 decreases as it supplies energy to that supply source. The decrease in current of inductance 416 ends at a time corresponding to time T4 in Figure 6, when SCR 414 is gated to conduct, the voltage at circuit point 426 becomes negative, and diode 424 becomes non-conductive. The voltage of the capacitor 418 is once again applied across the inductance 416 to begin increasing the current and energy stored in the inductance 416.

The control of the voltage across the horizontal deflection circuit 422 in the arrangement of Fig. 4 takes place as in the other illustrated embodiments by periodically adjusting the average of the increasing and decreasing current through the inductance 416, which in turn is controlled by a variable gate switching time T4.

Figure 7 illustrates the voltage generation components of the control, deflection and extreme anode in a television receiver incorporating the present invention.

In Fig. 7, an unregulated B + supply knob 10 is connected over a pulsed DC supply source, such as a rectifier connected to an AC power supply. A filter capacitor 13 is connected between the switch terminal 10 and ground to filter the pulsed DC current and generate a new operating voltage for the rest of the equipment. An adjustable switch in the form of an SCR 14 is anode connected to the switch terminal 10, and its cathode is connected at one end to the winding 16b of the transformer 16 '. The other end of the winding 16b is connected to the other end of the filter inductance 17. The other end of the filter inductor 17 is connected to ground by a filter capacitor 18. The connection point Br of the inductor 17 and the capacitor 18 is connected to the other end of the winding 16a of the transformer 16 '. The winding 16a acts as an input inductance to the horizontal deflection circuit, generally indicated at 22. The deflection circuit 22 includes an NPN transistor 23 whose emitter is connected to ground and whose collector is connected to the end of the winding 16a located farther from the junction point Br. The attenuator diode 25 is connected across the collector-emitter path of the transistor 23. The deflection winding 29 associated with the picture tube 31 is connected in series with the S-shaped capacitor 33, and this series combination is connected in parallel with the diode 25. The return capacitor 35 is connected in parallel with the diode 25 to supplement the capacitance of the winding 29 and to help provide the correct duration of the return interval. The winding 16c of the transformer 16 'is connected at one end to ground and at the other end via a rectifier illustrated as a diode 37 to the end anode of the picture tube 31 to peak rectify the return pulses so as to provide an extreme anode DC voltage to the picture tube. The horizontal oscillator, illustrated in block 38, provides operating signals at the horizontal deflection frequency, which are applied to the base of the transistor 23. The horizontal oscillator 38 also provides synchronizing pulses at the horizontal frequency, which are applied to the voltage control circuit illustrated in block 40. The control circuit 40 is connected to the junction point Br and also applied to the gate of the SCR 14 to control the SCR part in a known manner. Diode 342 is connected between ground and winding 16b and the connection point of inductance 17.

In normal operation, the voltage control circuit 10 Touches the SCR 14 to conduct at a certain time during the horizontal line interval. During the time period during which the SCR 14 is conductive, the current in the inductance 17 increases at a rate determined by the voltage across the winding 16b plus the difference between the regulated voltage at point Br of VBr and the untreated B + voltage across capacitor 13. At the end of the horizontal line interval, a return voltage pulse is generated over the capacitor 35. The voltage pulse is connected from the winding 16a to the winding 16b. The voltage pulse across the winding 16b has a polarity such that it tends to generate a blocking bias to the SCR 14 and reduce the current flowing in the inductor 17. The inductance 17 may be of any value required because during the return the inductance current flows in the diode 342 and capacitor 18. When the current in the winding 16b reaches zero, the SCR 14 becomes non-conductive in preparation for the next cycle of control operation. The voltage VBr is adjusted in the arrangement of Fig. 7 by modulating the conductivity of the SCR 14 by operating cycle modulation, which is accomplished by changing the time during the horizontal deflection period 16 7 5 2 4 6 during which the SCR 14 is gate controlled to conduct current.

If it is desired to compensate for the amplitude of the return pulse as a function of the beam current of the picture tube, the embodiment shown in Fig. 8 can be used.

In Fig. 8, parts corresponding to those in Fig. 7 are denoted by the same reference numerals. Figure 8 includes the winding 416 of the transformer 16 'at the side outlet. This side outlet divides the winding 416 into two portions 416a and 416b. Diode 442 is connected between ground and side output of winding 416. In the operation of the arrangement of Figure 8, the voltage control circuit 40 controls the gate to conduct the SCR 14 at a certain point in time during the horizontal line interval, which is adjusted to maintain a controlled voltage VBr across the capacitor 18 and the deflection circuit 22 at a substantially constant value. Adjusting the gating time from the SCR 14 causes the supply of a voltage across the inductance 17 during varying time intervals and results in different currents at the beginning of the return time interval, as described above. Changes in the beam current of the picture tube cause corresponding increases in the load on the capacitor 18 and in the current flowing through the inductance 17 at the beginning of the return interval. During the return interval, the return pulse present across the capacitor 35 is connected by the winding 16a to the winding 416. The portion of the pulse that occurs across the winding 416a renders the SCR 14 non-conductive when the pulse magnitude is equal to the unregulated DC voltage. Thus, the arrangement of Figure 8 provides reliable quenching of the SCR regardless of the magnitude of the inductance 17, as in Figure 7.

During the return interval, the diode 442 is conductive and the current in the inductance 17 decreases towards zero according to the sum of the return interval pulse occurring over the winding 416a and the controlled voltage VBr. At the same time, the inductance 17 is connected across the winding 416b by means of a diode 442 and a capacitor 18, and the inductance gap of the inductance 17 is effectively connected in parallel with the return winding 16a and the deflection winding 29, as in Fig. 1. The length of time that current flows through inductance 17 and during which diode 442 remains conductive during the return interval depends on the magnitude of the current flowing through inductance 17 at the beginning of the return interval. As a result, the increased beam current of the picture tube, which provides an increased current to the inductance 17 at the end of the return interval, causes the diode 442 75246 17 to remain conductive for a larger portion of the return interval. This effectively keeps the inductance 17 connected in parallel with the windings 16a and 29 for a larger portion of the return time, reducing the average inductance in parallel with the capacitor 35 and thus reducing the return time interval. As shown in Fig. 9, when the return time interval decreases so much that the return waveform 200 changes to waveform 210, the peak value of the return voltage increases. Thus, the arrangement of Figure 8 provides an increased return voltage as a result of the peak value of the increased beam current and thus provides controlled compensation together with the reliable quenching of the SCR of the arrangement of Figure 7.

Other embodiments of this invention will be apparent to those skilled in the art. In particular, the capacitor 18 can be connected to the switch terminal 10 instead of ground to filter the regulating voltage. Windings 416a and 416b may be independent windings instead of a single side-out winding of the transformer 16 '. The capacitance of the windings 16a and 29 may be adjustable to eliminate the need for a return capacitor 35. Likewise, the timing signal for the voltage control circuit can be obtained from other points instead of the horizontal oscillator, such as the transformer 16 '.

Claims (2)

A television controller coupling controller and comprising a controllable thyristor switch (12; 214; 314; 414), a storage inductor (16; 216; 316; 416; 17), a commutation line (20b; 220b; 320b; 420b; 16b); a horizontal deflection generator, which includes a high voltage generator as a load for image tubes, said elements forming a circuit coupled to a call for an irregular DC voltage to provide a current path for increasing the current in the storage inductor during the time intervals that vary wherein to the main current path of the thyristor switch, horizontal deflection signals are measured via the commutation line connected to a horizontal transformer of said deflector generator to control the time when said switch becomes nonconductive, the switching regulator 18; the switching regulator and the deflection generator for filtering the current in storage the inductor for forming a drive voltage for the deflector generator, a control circuit (36, 40) coupled to the deflector generator and to a gate of the thyristor switch to control the time when the thyristor switch becomes conductive to control the average of increasing and decreasing currents in said storage current drive voltage in the feedback mode, characterized by a combination, wherein a diode (24; 224; 324; 424; 342; 442) which is connected in a manner known per se to the output of the thyristor switch (12; 214; 314; 414) and supports a commutation voltage formed by means of commutation pulses, so that it is coupled to the commutation line (20b; 220b; 320b; 420b ; 16b) forms the bias of the main current path in the reverse direction, which is needed to quickly provide the thyristor switch without conducting substantial deceleration of the current in the storage inductor (16; 216; 316; 416; 17). The regulator of claim 1, wherein said deflection generator includes a deflection switch, and a first winding (16a), a deflection winding (29), and return capacitor means (35) coupled to said deflection switch for providing a path for off-flow intercurrent flow, wherein said return times are dependent on the inductance parallel to the capacitor means; the regulator further comprising one