DE2626085A1 - Synchronising and stabilising circuit for DC regulation in TV - with switching circuit to provide stabilised output insensitive to disturbance effects - Google Patents

Abstract

A synchronising and stabilising supply circuit operates on an A.C. voltage supply in conjunction with a regulator to generate a D.C. voltage, the amplitude of which is proportional to the ratio of the period of two drive signals. The circuit is for application in television receivers and minimises the effects of disturbances. The un-isolated stage of the receiver is coupled to an A.C. supply over a diode and capacitor and supplies the winding of a transformer. The transformer, transistor and diode coupled to the secondary winding operates as a regulator controlled by drive signals from a generator formed from a multi- vibrator and associated stages. Outputs of the circuit are coupled to an isolated stage to generate the d.c. output.

Description

Supply circuit with working and synchronized in switching mode Constant regulator The invention relates to a synchronized and stabilized Setting tool.

If a television receiver is to work optimally, then it has to be different Circuits of the receiver are supplied with a stabilized DC voltage (potential B +) will. There are many types of regulated supply circuits that can be used to create a can achieve such stabilization. One of these circuits is the one in switching mode regulated supply part.

A supply part that is regulated in switching mode is a very economical one Type of stabilized supply circuits, as the switching device alternates is switched off and on and the regulation by controlling the j respective duration of the switched-off in relation to the switched-on state of the switching device he follows.

To any by the constant switching of the switch-controlled It is to keep the disruptive influences caused by the supply part as low as possible expedient to synchronize the switching with the sync signals that are used for the synchronization of the deflection circuits are used. In addition to the sync signals the level B + to be stabilized must also be given to the switching device, to have the necessary feedback to control this level.

In television receivers, where it is used to protect the user from electrical Shock is desired, the chassis from the AC voltage source with grounded However, to isolate the ground pole requires a lot of component or a complicated one Construction of an isolating transformer to the potential B + and the synchronous signals to couple to the switching device.

In addition, television receivers need a line deflection system of the in U.S. Patent X 452 244 of the type described with two double-ended conductors Switches use an input choke between the source of voltage B + and the commutating double-ended switch to short-circuit the voltage B + during the commutation interval (i.e. when the commutation switch is switched on) to prevent.

According to the invention includes a synchronized and stabilized Power supply circuit for a television receiver operating in switching mode Regulator or stabilizer that can be connected to an alternating voltage source can to generate a DC voltage with an amplitude proportional to the Duration of a first drive signal state in relation to the duration of a second drive signal state is. An oscillator that can be coupled to a synchronizing signal source supplies a switching signal, which has a first predetermined phase relationship to the synchronizing signals. With the controller operating in switching mode and the oscillator is a modulation device coupled to generate a control signal which has a second predetermined Phase relationship compared to the switching signal and has an amplitude that is proportional to the Is the amplitude of the DC voltage. With the nodulation device and the one in switching mode working controller is coupled to a device containing a drive signal generator, which causes the first drive signal state when the control signal is triggered and the duration of the first drive signal state in relation to the duration of the second drive signal state depending on the amplitude of the control signal controls.

Details of the invention are given below using exemplary embodiments explained with reference to drawings, Figure 1 shows, partly in block form, a non-isolated Part of a synchronized and stabilized power supply circuit for a television receiver; FIG. 2 shows, also partially in the form of a Rlock, a preferred embodiment an isolated part of the synchronized and stabilized supply circuit of the television receiver; Figures 3A to 3J are normalized representations of waveforms, as shown at various points in the circuit diagram of a first embodiment Figure 1 and the circuit diagram of Figure 2 appear; Figures 4A to 4J are standardized Representations of waveforms as they appear at various points on the schematic a second embodiment of Figure 1 and the circuit diagram of Figure 2 appear.

Figure 1 illustrates the non-isolated portion 42 of the television receiver according to Figures 1 and 2. An AC voltage source (not shown) with a grounded reference or ground pole is via a diode 16 with a filter capacitor 18 connected to a terminal 20 opposite a positive DC voltage more grounded Gain mass. The connection 20 is via a winding 22a of an isolating transformer 22 is connected to the collector electrode (I) of a switching transistor 24. The winding up 22a is magnetically coupled to the terminals 22b and 22c of the isolating transformer 22, in the polarity indicated by the black dots. A first connection the cover 22b is as terminal J and another connection is the winding 22b referred to as terminal Er. A first connection of the winding 22c is to the K terminal connected, and another connection of the winding 22c is designated as L terminal. The emitter electrode of transistor 24 is connected to the grounded ground.

Terminal 20 is also connected to the cathode through resistor 104 a zener diode 106 connected. The anode of the zener diode is connected to the grounded Wet. A filter capacitor 108 is connected in parallel with the Zener diode 106. the Zener diode 106 ensures that a stabilized voltage with respect to its cathode grounded wet. The cathode of the zener diode 106 is across a collector resistor 110 is connected to the collector of a transistor 112, the emitter of which is connected to the grounded Wet lies. The collector of transistor 112 is also across a resistor 117 to the base of a transistor 114 and also to a terminal 3 of a monostable Nultivibrators (monovibrator) 32 connected. The emitter of transistor 114 is coupled to the cathode of the zener diode 106.

The collector of transistor 114 is through an integrating network 117, consisting of the parallel connection of a capacitor 116 and a resistor 118, connected to grounded earth. The collector of transistor 114 is also connected to the base of a transistor 120 via a resistor 122.

The emitter of transistor 120 is grounded. The collector of transistor 120 is connected to the cathode of Zener diode 106 via a resistor 124 out, further through a resistor 128 to the base of a transistor 126 and finally nor to a first input 130 of a NAND gate 132 having two inputs The emitter of transistor 126 is connected to grounded point, and his collector is via a resistor 134 with the cathode of the Zener diode 106 and also with a terminal 4 of the monovibrator 32 is connected. The transistors 112, 114, 120 and 126 in connection with the circuit arrangement assigned to them Pulse shaper and peak detector 28.

A second input 136 of the NAND gate 132 is via a capacitor 138 with earthed wet and via a resistor 140 with the output of this element 132 connected. Capacitor 138, resistor 140 and NAND gate 132 form an auxiliary oscillator 26. The output of the NAND gate 132 is connected to a terminal 5 of the monovibrator 32 connected.

The cathode of the Zener diode 106 is also connected to a terminal 14 of the Monovibrator 32 and connected to the collector of a transistor 142. A clamp D of a winding 40a of an isolating transformer 40 is through a resistor 144 to the base of the transistor 142, furthermore via a resistor 146 to the base of the transistor 112 and finally via a parallel connection of a protection and Clamping diode 148 and resistor 150 connected to grounded ground. The other The winding terminal is connected to earthed wet. The winding 40a of the transformer 40 is magnetically coupled to a winding 40b of this transformer, namely in the polarity indicated by the black dots. A first clamp of the Winding 40b is labeled N and the other terminal is labeled N.

The emitter of transistor 142 is through an integrating network 151, consisting of the parallel connection of a capacitor 152 with the series connection a resistor 154, the ohmic element of a potentiometer 156 and one Resistor 158, connected to a grounded diasse. The transistor 142 and the integrator 151 form a peak detector ~ 30.

The wiper of the potentiometer 156, designated as terminal F. is coupled to the base of a transistor 160. With the potentiometer you can the voltage at the base of the transistor 160 with respect to the peak value the voltage at the base of transistor 142 can be adjusted. The transistor 160 forms in conjunction with a transistor 162 and associated circuitry a voltage comparator and differential amplifier 34.

The emitters of transistors 160 and 162 are across a resistor 164 connected to earthed ground. The collector of transistor 160 is across a resistor 166 connected to the cathode of the zener diode 106, and the collector of the transistor 162 is led to the cathode of the Zener diode 106 via a resistor 168. At this Connection mode, the voltage at the collector of transistor 162 increases when the Voltage at terminal F increases within a predetermined voltage range determined by a reference voltage at the base of transistor 162 will.

The collector of transistor 162 is also across the series connection a resistor 170 and a capacitor 172 to a terminal 10 of the monovibrator 32 connected. The resistor 170, the capacitor and the voltage on the collector of transistor 162 determine the width of the logic or binary value 0 having Part of the driving pulse that is delivered to a terminal 1 of the monovibrator 32. The connection point between resistor 170 and capacitor 172, which acts as a terminal G is connected to the terminal 11 of the onovibrator 32. The base of transistor 162 is connected to the cathode of a zener diode 174 and also via a Resistor 176 connected to the cathode of Zener diode 106. The anode of the zener diode 174 is connected to earth ground. The zener diode 174 and the resistor 176 form one ReSerenzspannungsquelle 38, which for a substantially constant voltage on the Base of transistor 162 provides and thus the reference value for the voltage comparator and differential amplifier 34 presets.

The output terminal 1 of the monovibrator 32, referred to as terminal II is across the parallel connection of a resistor 178 and a capacitor 180 connected to the base of a transistor 182. The base of transistor 182 is also about a resistor 184 connected to ground ground. The emitter of transistor 182 is grounded and its collector is on the one hand with the first terminal of a winding 186a of a driver transformer 186 and on the other hand via a high-frequency dissipating network from the series connection a resistor 188 and a capacitor 190 connected to grounded ground. The other terminal of winding 186a is connected through resistor 192 to the terminal 20 and connected to grounded earth via a capacitor 194.

Another winding 186b of driver transformer 186 related to of winding 186a is polarized in the manner indicated by the black dots one end is connected to earthed water, while the other end is over the parallel connection of a capacitor 196 and a resistor 19 with the base of transistor 24 is connected. The base of the TransistDrs 24 is also over the parallel connection of a resistor 200 and a protective diode 202 with grounded Ground connected. The emitter of transistor 24 is connected to earth ground, and since Collector (terminal I) consists of a high frequency dissipating network from the series connection of a resistor 204 and a capacitor 206, with grounded Ground connected.

The rn-lsistor 182 and the associated circuitry form a driver network 36, which is a power amplification and a polarity reversal of the at the terminal E of the monovibrator 32 output signal causes.

FIG. 2 shows, partly in block form, a preferred embodiment of the isolated part 44 of the synchronized and stabilized power supply of the television receiver according to Figures 1 and 2. The terminals J, K, L, M and N in FIG. 2 are connected to the correspondingly designated terminals in FIG.

The terminal J of the winding 22b is connected to the anode of a diode 52. The cathode of diode 52, labeled terminal G, provides a pulsating one DC voltage to a deflection system 53 and is one with the anode Thyristor 54 and connected to the cathode of a line diode 5.6. The thyristor 54 and the row diode 56 form a commutation switch 58. The cathode of the The thyristor 54 and the anode of the row diode 56 are connected to the reference potential of the isolated part 44 connected. Terminal C is also via a commutation network 62 connected to the anode of a thyristor 60. The commutation network 62 contains a series connection of a commutation coil 64, a first commutation capacitor 66 and a second commutation capacitor 68. From the connection point between An auxiliary capacitor 70 leads the commutation capacitors 66 and 68 to the reference potential. With the thyristor 60, a row diode 62 is connected in an anti-parallel manner, to form a so-called trace switch 730 The anode of the thyristor 60 is Via a winding group 74 of a deflection yoke and one connected in series with it S-forming capacitor 76 connected to the reference potential The anode of the thyristor 60 is also via a series circuit consisting of a winding 78a High voltage transformer 78 and a DC blocking capacitor 80 with Reference potential connected. Zisclaen the anode of the thyristor 54 and the control electrode of the thyristor 60 is a control network 98 for the trace thyristor, which a resistor 78, a capacitor 280, a capacitor 282, a resistor 284 and an inductor 286 and serves to control the trace thyristor 60 at correct point within the deflection interval (t0-t0 'in Figures 3 and 4).

A winding 78b of the high voltage transformer 78 lies with her one end to the reference potential and its other ande to a high-voltage multiplier and rectifier circuit 82 connected. An output terminal 84 of this high voltage multiplier and rectifier circuit 82 is connected to a picture tube (not shown). The pulses induced in the winding 78b are multiplied by the high voltage and Rectifier circuit 82 rectified and added to the rectified at terminal 84 High voltage potential too deliver what to generate the necessary Beam current in the picture tube is required. One end of a coil 78c is connected to the reference potential, and the other end of this winding leads to a unit 96 which has a norizontal oscillator and a circuit for automatic Phase control (APR) included.

The terminal K is connected to the anode of a diode 86, the cathode of which is connected to the reference potential via a capacitor 88. The cathode of the Diode 8-6, which is a source of reference potential B +, is also across a resistor 208 is connected to the N terminal. Terminal M is via the parallel connection a resistor 210 and a filter capacitor 212 connected to reference potential. The cathode of the diode 86 also leads via a resistor 214 to the cathode of a Zener diode 216, the anode of which is at reference potential.

The zener diode 216 is a filter capacitor 21E connected in parallel. The cathode of the Zener diode 216 is through a resistor 220 and one in series with it lying parallel circuit of a Zener diode 224 and a capacitor 226 with Reference potential 1 connected. The cathode of diode 224 is connected to terminal 14 ciros monostable multivibrator (monovibrator) 222, and the anode of the diode 224 is connected at the reference potential. The terminal 14 of the monovibrator 222 is also connected in series a resistor 228 and a capacitor 230 to the terminal 10 of this monovibrator tied together. The connection point between resistor 228 and the capacitor 230 is connected to terminal 11 of the monovibrator 222. An output terminal 6 of the monovibrator 222 is via a resistor 232 to the base of a switching transistor 234 and connected to the reference potential via a fast discharge diode 236. The resistance 228, the capacitor 230 and the voltage at terminal 14 of the monovibrator 222 determine the width of the part of the an containing the logical or binary value 1 the output terminal 6 of the monovibrator 222 generated signal.

The collector of transistor 234, which has a control signal with a to the Potential B + provides proportional amplitude, is coupled to terminal N and also via a high-frequency dissipating network, consisting of a series connection a resistor 240 and a capacitor 242, connected to the reference potential. The terminals 3 and 7 of the monovibrator 222 are at the reference potential. The monovibrator 222, the transistor 234 and the associated circuit arrangement form a modulator 90

The cathode of the zener diode 216 is also across a resistor 244 to terminal 1 of unit 96 (horizontal oscillator and tSR circuit) and with the reference potential via a parallel connection of a discharge capacitor 246 for high frequencies and a filter capacitor 248 for low frequencies tied together. Terminal 16 of unit 96 is at the reference potential. Hit the oscillator and APR unit 96 is also connected to a sync signal source 92, which is a provides switching signal occurring at line frequency, with the aid of which the output A signal supplied by unit 96 is brought into the correct phase position in order to the pulse generated by the winding 7c with that of the synchronous signal source 92 to synchronize the supplied sync signal. The output A of unit 96 is Via a series connection of a high frequency choke 250 and a resistor 252 connected to terminal 5 of the monovibrator 222.

The connection point between choke 250 and resistor 252 is across a resistor 254 to the reference potential and via the series connection of a Resistor 256 and a capacitor 258 connected to the base of a transistor 260. The connection point between resistor 256 and capacitor 258 is via a Capacitor 262 connected to the reference potential. The resistor 256 and the capacitor 262 cause a delay in the signal between output A of unit 96 and the base of transistor 260. The base of transistor 260 is through a Resistor 264 coupled to the reference potential. The emitter of transistor 260 is at reference potential, and the collector of transistor 260 is through a resistor 266 to the cathode of the Zener diode 216 and through a resistor 270 to the base one Transistor 268 connected. The base of transistor 268 is also via a Capacitor 272 coupled to the reference potential. The resistor 270 and the capacitor 272 form a pulse stretcher and introduce some additional delay. The emitter of transistor 268 is connected to the cathode of Zener diode 216, and the collector of the transistor 268 is connected to the reference potential via a resistor 274 and coupled to the control electrode of thyristor 54 via a capacitor 276. The transistors 260 and 268 form a with the associated circuit arrangement pulse stretching and decelerating network 94.

The transistor 24 forms in its interaction with the diode 16, the capacitor 18, the isolation transformer 22, the diode 52, the diode 86 and the Capacitor 88 is a constant regulator operating in switching mode. This so-called "Switching regulator" generates an operating potential P +, the amplitude of which is proportional to the Switch-on duration of the transistor 24 in relation to the switch-off duration of the transistor 24 is, vJobhe switching of the transistor 24 is carried out by drive signals.

Since the non-insulated part 42 (Figure 1) in conjunction with the insulated Part 44 (Figure 2) works are explained in the following explanation of the mode of operation consider both Figures 1 and 2 at the same time. The way of working is initially with the aid of the solid curves of FIGS. 3A to J and 4A to 4J and then explained with reference to the curves drawn in dashed lines.

An alternating voltage source (not shown) supplies an alternating voltage, which is rectified with the diode 16 and filtered with the capacitor 18, in order to obtain a DC voltage with respect to the earthed ground at terminal 20.

The direct voltage appearing at connection 20 is used for the supply of the non-isolated part 42 of the television receiver according to FIGS. 1 and 2.

Before energy is transferred from winding 22a to windings 22b and 22c can be transmitted to the supply of the isolated part 44 of the television receiver According to Figures 1 and 2, the transistor 24 must be switched off and on alternately In this way, an alternating flux is generated in the core of the isolating transformer 22 to create. If the transistor 24 is not subject to such switching operation, then no voltage B + is generated at the cathode of the diode 86, so that at the terminal D of the winding 40a of the isolating transformer 40 also a signal appears. a missing one Signal at terminal D, the transistor 112 is blocked, so that at terminal E a logical 1 appears.

The level at the terminal that corresponds to the logical or binary value 1 E leads to the blocking of the transistor 114o. It is assumed that the non-isolated Part 42 has previously been de-energized or switched off for a longer period of time, so that the collector of transistor 114 has the potential of the grounded wet (logical O). If there is a logic 0 at the collector of transistor 114, then leads the base of transistor 120 also has a logic 0, so that transistor 120 is blocked When transistor 120 is blocked, the collector of this transistor is the base of the transistor 126 and the input 130 of the NAND gate 132 at the potential of the logical 1e If there is a logical 1 at the base of transistor 126, appears on Collector of this transistor a logical Oe FIit the logical 1 at the terminal E and a logic 0 at the collector of transistor 126 speaks of the monovibrator 32 for a positive signal change at its terminal 5. With a logical 1 at the input 130 of the NAND gate 132 is the terminal 5 of the tonovibrator 32 alternately from a logical 1 switched to a logical 0, with one through the Capacitor 138 and resistor 140 determined frequency.

In addition, in the absence of a signal at terminal D of the winding 40a, the transistor 142 is blocked, so that the voltage at the terminal F at the logic value 0 is, with which the transistor 160 is blocked and the. Transistor 162 in maximum Conductivity is. When the transistor 162 is at its maximum conductivity the voltage at the collector of transistor 162 to a minimum value which is determined by the Zener voltage of the Zener diode 174 and determined by the resistors 164 and 168 is. Because the voltage at the collector of transistor 162 is less than the Zener voltage the Zener diode 106, the charging speed of the capacitor 172 is less than with transistor 162 blocked. This slow charging rate of the capacitor 172 leads to the fact that the output E of the monovibrator 32 pulse des Logic value 1 has a minimum duration (maximum monostable period).

The change from logic 0 caused by the auxiliary oscillator 26 to logic 1 at terminal 5 of the monovibrator 32, j each cause a change from logical 0 to logical 1 at terminal H and a negative change at the Clamp G.

When capacitor 172 charges through resistor 168, it begins the voltage at terminal G to become more positive.

When the voltage at the terminal G one by the characteristics of the monovibrator 32 reaches a certain threshold value, the output H changes from a logical 0 to a logical 1.

Every change from 1 to 0 at output H, as it did at t0 in FIG. 3H shown results in transistor 182 being turned off and at the base of the Transistor 24 generates a positive voltage with respect to the grounded wet. When the base voltage of the transistor 24 is positive, a current flows from the terminal 20 via the winding 22a of the isolating transformer 22 and via the transistor 24 to grounded wet. The one during the saturation of transistor 24 by the winding Current flowing in 22a causes a logic 0 at terminal I, as shown in FIG. 31 is shown, and results in that at the terminals J and K of the windings 22b and 22c a negative potential appears with respect to the terminal L as shown in Figure 3J is.

When the signal at output H of the monovibrator 32 changes from 0 to 1, as shown at t6 in Figure 311, transistor 182 goes into saturation brought, with which at the base of the transistor 24 a opposite to the grounded Hasse negative potential appears. With a negative potential at the base of the transistor 24 this transistor is blocked, so that during the saturation of the transistor 24 field built up in the isolating transformer 22 collapses. The collapse of the Field in the isolation transformer 22 induced at the terminals J and the windings 22b and 22c, a positive voltage with respect to the terminal It, as shown in Figure 3J is. jenn at the terminal J and K of the windings 22b and 22c a signal of the in Figure 3J is generated, then a pulsating appears at terminal C. DC voltage, and the + voltage is developed at the cathode of the diode 86. With B + at the cathode of diode 86, the oscillator and ILPR unit 96 begins to generate a signal at its output A, as shown in FIG. 3A. That The signal at output A triggers the monovibrator 222, which at terminal 6 triggers this MonovilDrator-s generates a signal which is similar to that shown in Figure 3D Signal, j is, however, of constant amplitude. That at terminal 6 of the monovibrator A signal appearing 222 results in transistor 234 being switched and on the terminal D generates a signal of the waveform shown in Figure 3D. The amplitude of the signal at terminal D is directly proportional to the amplitude of that at the cathode voltage B + generated by diode 86. The signal at output A of unit 96 becomes formed in network 94 and delayed so that at terminal B that shown in Figure 3B The gate control signal appears. By specific choice of components in the pulse-shaping and delaying network 94 and in modulator 90 it is also ensured that during the initial start-up of the supply circuit (. i.e. before to) at the Terminal D of the transformer generates 40 pulses be before at the terminal B generates pulses.

The change from 0 to 1 at output B of the pulse shaping and decelerating Network 94 takes place at time t1 (see FIG. 3B) in order to ensure that the commutation switch 5 is only switched on after the voltage at the Terminal J has become negative. The voltage at terminal J remains for a period of time t0-t6 negative. Since the commutation switch 58 stops conducting at time t4, as shown in FIG. 3C, flow occurs during the conductive state of the commutation switch 58 no noticeable current through diode 52. The deflection system works in a known manner as described and produced in U.S. Patent 3,452,244; pulses at the winding 78c which are fed to the oscillator and APR unit 96 and compared with the signals from the synchronizing signal source 92 to obtain at the output A to generate a signal, which the synchronization of the synchronsignalouelle 92 supplied signals with the pulses generated on the winding 7tc upright.

At time t0, a pulse is applied to terminal D of winding 40a began. This positive pulse is triggered via resistor 146 the saturation of the transistor 112, so that a logic 0 appears at the terminal E. The logic 0 at terminal E causes a base-emitter current in transistor 114 across resistor 113, thereby saturating transistor 114. With saturated Transistor 114 gets the voltage at the collector of transistor 114 the logic value 1. With a logic 1 at the collector of transistor 114, transistor 120 becomes due to the base-emitter current caused by the resistor 122 into saturation brought. When transistor 120 is saturated, the voltage is at the input 130 of the NAND gate 1-2 to the logic value 0 and the voltage at the base of the transistor 126 also has the logic value 0. Hit a 0 at input 1) 0 of the NAND element 132 the local oscillator 26 is switched off, and at the output of the NAND gate 132 one logical 1 maintained. With a logic 0 at the base of the transistor 126 is the Collector of transistor 126 on a logical 1. egg one logical 1 at the collector of transistor 132 and a logical 1 at the output of the NAND gate 132, the output H of the monovibrator 32 (Figure 3 H) goes from 1 to 0, when a change from 0 to 1 takes place at terminal D of winding 40a, as it does at t0 in Figure 7, D is shown.

By changing the time constant of the integrator 151 of the peak detector 0 two different operating modes can be achieved. Any of these modes of operation is shown as a separate embodiment of a non-isolated portion 42 of the television receiver considered.

In the first embodiment, an integrator 151 is used, its Time constant significantly longer than the period (t0-t0 ') of the pulse repetition frequency of the oscillator and APR unit 96 is 0 in the case of such a long time constant do the positivean generate pulses at terminal D of winding 40a on capacitor 15? a voltage that is nearly constant and roughly equal to the maximum amplitude the positive pulse at terminal D is. There is therefore a voltage at terminal F. which is proportional to the voltage across capacitor 152 and that in Figure 3F corresponds to the voltage shown.

Assuming that the amplitude of the positive pulse is at er Terminal D within the predetermined response range of the voltage comparator 34, the voltage at the collector of transistor 162 is proportional to the voltage at terminal F.

At time t0, the voltage at terminal G of the monovibrator 72 negative as shown in Pigur 3G. The voltage begins after time t0 at the terminal G to increase exponentially at a rate determined by the Voltage at the collector of transistor 162 is determined. When the tension on the Terminal G the threshold value set by the characteristics of the Honovibrator @ 2 reached, the output H of the changes Monovibrators 32 of one logic 0 to a logic 1, as shown in Figure 3II at t6.

Signal changes at terminal 11 lead to the corresponding ones as described above Signal change at terminals I, J and K, if the conditions for an operation of the auxiliary oscillator 26 are satisfied. The signal changes on inhibitors I, J and K ensure the operation of the deflection system 53 and the generation of the voltage B + at the cathode of the diode FC6, thus maintaining the operation of the insulated part 44 is obtained.

The modulator 90 and the pulse shaping and delaying network 94 are designed in their components so that the generation of Torstetierimpulses at terminal B during the transition period until the positive pulses at the terminal C the correct phase position with respect to that supplied by the sync signal source Signals have been delayed to allow current to flow through diode 52 during the To prevent conductivity of the commutation switch 58. The said delay thus prevents that during the start-up of the supply circuit over moderate Current flows through the diode 52.

As the voltage B + increases, the pulse amplitude also increases at terminal D, as shown by the dashed curve in Figure 3D, so that a higher voltage is generated at the terminal F (see FIG. 3F) and the Voltage at terminal G exceeds the threshold value at time t5 instead of at time t6 reached. If the voltage of terminal G reaches the threshold value faster, then is the time during which the voltage at terminals H, I, J and li on the logic value 0, are shorter during each deflection interval. This change to terminals J and K causes the peak voltage at terminal J and the Voltage B + drop to values as indicated by the dashed curves in FIG are shown even if the peak-to-peak voltage at terminals J and K is greater than is under the original conditions. By maintaining a relative constant Peak voltage at terminal J and a relatively constant one Voltage F5 + causes the isolated portion 44 to operate relatively smoothly.

In a second embodiment, the integrator 151 has a time constant which is shorter than the period of the pulse train frequency of the oscillator and APR unit 96 is. In the case of this short time constant, the positive pulse causes the Terminal D of winding 40a at the emitter of transistor 142 has a voltage that is approximately equal to the maximum amplitude of the generated at terminal D during the interval t0-t1 positive momentum. At the terminal F a voltage is generated that corresponds to the voltage at the emitter of transistor 142 is proportional. At time t0 appears on Terminal F a voltage which exceeds the Zener voltage of the Zener diode 174. This leads to the riaximal conductivity of the transistor 160 and the blocking of the Transistor 162. When transistor 162 is blocked, the collector of this is located Transistor at a voltage which is approximately equal to the Zener voltage of the Zener diode 106 is, whereby the capacitor 172 moves relatively quickly from the prevailing at t0 Charges value as shown in Figure 4G.

The point at which the voltage at terminal G corresponds to that shown in Figure 4G reached, determines the point in time when the signal is on Output H of the monovibrator 32 changes from 0 to 1.

At time t1, the voltage at terminal D becomes negative, which means the transistor 112 is blocked and a logical 1 appears at the terminal 33. With a logical 1 at the terminal E, the transistor 114 is blocked, and the Capacitor 116 begins to turn out across resistor 118 and the series circuit the resistor 122 and the base-emitter junction of the transistor 120 to discharge. Because of the relationship selected here between the subsequent period at the terminal D of the winding 40a of the isolating transformer 40 generated pulses at the time constant the off capacitor 116, resistor 118 and resistor 122 existing circuit drops the voltage at the collector of transistor 114 between the pulses appearing at terminal D are not so far off that the transistor 120 does not remain in saturation. Therefore the input 130 of the NAND gate remains 132 at a logical 0, and the output of this element remains at a logical 1.

With a negative voltage at the terminal D of the winding 40a, the transistor 142 is blocked, and the capacitor 152 begins to pass through the resistors 154, 156 and 150 as shown in Figure 4F between t1 and t0 '. At the time t2, the voltage at terminal F is equal to the Zener voltage of Zener diode 174. If the voltage at terminal F just drops below this limit, the transistor blocks 160, and transistor 162 is placed in the state of maximum conductivity.

During the interval t2-t6 the transistor 1162 remains maximally conductive, and the charging speed of the capacitor 17 is lower than when it is locked Transistor 162 of Pall w & r as shown in Figure 4G. At time t6 the output signal H changes from 0 to 1, as can be seen in FIG. 4H, and because at this point in time the voltage at terminal G reaches the threshold value, as can be seen in Figure 4G.

Positive and negative signal changes at output 11 of the monovibrator 32 perform as described above under conditions in which the local oscillator 26 works, to positive and negative signal changes at terminal 1 and at the Terminal J.

When the pulse amplitude at terminal D of winding 40a increases, as shown by the dashed curve in Figure 4D, the increases Maximum amplitude of the voltage at the terminal F, as shown in FIG. 4F. These Changing the maximum voltage at terminal F increases the time during which the capacitor 172 is charged at the faster rate (see FIG 4G), thus reducing the total time to charge the capacitor 172 on the threshold.

This decrease in the total time to charge capacitor 172 to the threshold also reduces the length of time during which the output fI of the vibrator 32 is on a logical: 0 (see FIG. 4E), and shortened the duration of the saturation of the transistor 24. This leads to the compensation of an increase the DC voltage at terminal 20, which originally caused the increase in the pulse amplitude at terminal D. This compensation is when looking at the figure 4J clearly where you can see that the positive peak voltage of the closed Control loop remains roughly the same thanks to the change in the saturation period of the transistor 24 due to an increase in the pulse amplitude at the terminal D of the Winding 40a.

The above-described supply switch of a television receiver ensures that the DC voltage B + is kept constant, as well as synchronization of the switching transistor 24 with the line frequency to reduce interference as well as to isolate the external voltage source from those accessible by the user Parts that are connected to the reference potential. By synchronizing the DC voltage B + with the conductivity of the commutation switch 58 is also an input throttle in the deflection system 53 avoided.

In a specific embodiment of the invention, which is in the Corresponding to the arrangement shown in FIGS. 1 and 2, the honovibrator 32 can be used the component SN 74121 from Texas Instruments, for the oscillator and APR unit 96 the component TEA 920 from Philips and for the nonovibrator 222 the component SN 74121 from Texas Instruments can be used.

Claims (9)

Claims a synchronized and stabilized supply circuit with one that can be connected to an AC voltage source and operates in switching mode Constant regulator for generating a direct voltage (B +), the amplitude of which is proportional the duration of a first drive signal state in relation to the duration of a second Driving signal state is, furthermore with an oscillator arrangement which is connected to a synchronous signal source can be coupled to a switching signal with a first predetermined phase relationship to deliver against the synchronous signals, as well as with a modulating device, those with the constant regulator working in switching mode and with the oscillator arrangement is coupled to generate a control signal having a second predetermined Has a phase relationship with respect to the switching signal and has an amplitude that is proportional the amplitude of said DC voltage; is that there is no c h n e t that with the modulating device (90) and with that in switching mode working constant regulator (22, 24, 6) a drive signal generator (28, 0, 32, 34, 38, 40) containing device is coupled, which in response to the triggering of the control signal triggers the generation of the first drive signal and which state the duration of the first drive signal state in relation to the duration of the second drive signal state depending on the amplitude of the control signal. 2. Supply circuit according to claim 1, characterized in that sec the modulating means (90) includes: one with the oscillator assembly (96) coupled arrangement (222) for generating the control signal for a first predetermined Duration whether this control signal has said second predetermined phase relationship has compared to the switching signal; one with the arrangement generating the control signal (222) and with which the drive signal generator (28, 30, 32, 34, 38, 40) containing device coupled reinforcing assembly (234), which the Amplitude of the control signal lead said first duration depending on said Simultaneously controls. Supply circuit according to Claim 2, characterized in that the line direction containing a drive signal generator (28, 30, 32, 34, 38, 40) comprises: a first coupled to the modulating assembly (90) Peak detector (30) for generating a control voltage (3F) proportional to the Is the peak amplitude of the control signal. A reference voltage source (38); one with voltage comparator coupled to said first peak detector (30) and said reference voltage source (38) (34) for generating a charge voltage proportional to the control voltage; one with the voltage comparator (34), the module-generating arrangement (O0) and the switching mode working constant regulator (22, 24, 86) coupled monostable multivibrator (32), the first drive signal state in response to the triggering of the control signal (0) triggers and which triggers the second drive signal state when one of the Charging voltage generated voltage is equal to a predetermined voltage value. 4. Supply circuit according to claim 3, characterized in that the device (28, 30, 32, 34, 38, 40) containing a drive signal generator also an auxiliary oscillator coupled to the monostable cultivibrator (32) (26) to repeatedly trigger the first drive signal state when said DC voltage is below a predetermined amplitude. 5. Supply circuit according to claim 4, characterized in that the device (28, 30, 32, 34, 38, 40) containing a drive signal generator further includes a green transformer (40) to provide an isolated coupling between the modulating device (90) and connected to an AC voltage source Obtain Konotant regulators. 6. Supply circuit according to claim 2, characterized in that there @ The Linrichtung containing a drive signal generator has: a first peak detector (: 0) coupled to the modulating device (90), one of the peak amplitudes of the control signal during said first period (40) generates the same control voltage (4F) and that after said first duration decreasing the control voltage (4F) at a predetermined rate; one Reference voltage source (3 °); one with the first peak detector (30) and the reference voltage source (38) coupled voltage comparator (34) which generates a first charging voltage, when the control voltage (4F) is greater than the reference voltage, and the one second Charging voltage generated when the control voltage (4F) is less than the reference voltage is; one with the voltage comparator (34), the modulating device (90) and monostable coupled to the constant regulator (22, 24, 86) operating in switching mode Multivibrator (32), which in response to the triggering of the control signal, the first The state of the drive signal (4H) causes the generation of the second drive signal state triggers when a voltage generated by the first and the second charging voltage is equal to a predetermined voltage value. 7. Supply circuit according to claim 6, characterized in that the means (28, 0, 32, 34, 38, 40) including a drive signal generator has an auxiliary oscillator coupled to the monostable multivibrator to repeatedly triggering the first drive signal state when said DC voltage is less than a predetermined amplitude. P. supply circuit according to claim 7, characterized thereby, that the device (22, 30, 32, 34, 38, 40) containing a drive signal generator further comprises an isolating transformer (40) to provide an isolated coupling between the modulating device (90) and that containing the drive signal generator To create facility. 9. Supply circuit according to claim 1, characterized in that a delay device (94) is coupled to the oscillator arrangement (96), to generate a delayed switching signal (3B); that with the working in switching mode Constant regulator (22, 24, 26) and with the delay device (94) and with the Oscillator arrangement (96) a deflection device (53) is coupled to repetitive Generate deflection cycles that oppose a third predetermined phase relationship have the synchronizing signals, so that between the constant regulators working in switching mode and the deflector only during a power refueling period of the deflection cycle Electricity flows. L e r s e i t e