DE2322875C3 - Circuit arrangement for heating the picture tube of a television receiver - Google Patents

Description

The invention relates to a circuit arrangement as it is assumed in the preamble of claim 1.

In US-PS 34 62 640 a circuit arrangement for heating the picture tube of a television receiver is with a switch that can be switched between reception and readiness is described in its reception position the picture tube is supplied with the full heating voltage and in its standby position the picture tube a reduced heating voltage is supplied. In this known circuit, the heating energy for the Picture tube obtained from the mains transformer, and a series resistor is inserted in the heating cable, which is in the standby position the picture tube heating voltage is reduced by its voltage drop and in the Receiving position is short-circuited, so that the picture tube is heated with full voltage. the

Deflection noises are not included in the measures for the heating voltage encapsulation of the picture tube.

The object of the invention consists in specifying a 1 lcizschaluing for a picture tube in which not just do without a mains transformer! will can, but also the reduced heating output in the Bcrcitschaflsstelliing not with ohmic losses and the resulting heat development is bought.

This object is achieved by the characterizing features of claim i.

In the arrangement according to the invention, the line deflection circuit is used for the desired control the picture tube heating voltage is used. The formation of the line deflection circuit is common here of importance insofar as they are responsible for the function of changing the picture tube heating voltage is. The invention utilizes line deflection such as that disclosed in U.S. Patent 34 52 244 has become known and is now generally referred to as a commutator circuit. In accordance with the picture tube receives the heating voltage via a coupling circuit, which consists of part of a transformer consists, from a voltage source under control by the controlled by the line oscillator Return switch supplied, whose duty cycle, which determines the size of the heating energy, under aiv.lerem is determined by the duty cycle of the trace switch, so that there is an influence this Schaller with the help of the standby position or reception position determining switch can change the size of the heating energy for d'c picture tube.

The circuit according to the invention does not require a mains transformer, but all operating voltages are derived from the line deflection circuit. With regard to the possibility of a circuit integration is the renouncement of a mains transformer as well as cncrgicvcrzerrende and heat-generating Resistances of great importance.

The invention is of particular interest to a deflection circuit of that described in US Pat. No. 3,452,244 Kind, because by means of an additional winding on one existing in such a deflection circuit Transformer a heating voltage for the picture tube can be generated without its own step-down transformer can. In a relatively simple way, an inductance that gates the trace thyristor, one Apply additional winding while the receiver's changeover switch is parallel to this forward switch is switched. When the receiver is switched off, this switch is closed and prevents generation all DC voltages with the exception of those for the line oscillator of the receiver. The line oscillator therefore also provides a control signal for the return switch and enables a heating voltage to be generated for the picture tube. The short-circuiting of the feed switch by the closed switch however, it changes the tuning of the commutator circuit and thereby sets the heating voltage opposite that which is normally generated and fed to the picture tube. When switching on again of the receiver, the switch is then opened and the heating voltage increases! to their normal value. This increases the emissivity of the picture tube to its full value at a rate that the operational readiness of the various signal processing stages comes so close that the picture tube is practically immediately operational can be spoken.

Furthermore, a resistor-rectifier combination can be connected in series to the filament of the picture tube to the size of the heating voltage in the receiving or standby state of the receiver to determine. Furthermore, you can see the ratio of the supply voltage in the receiving and Bercitschaflsstatus Determine by a suitable choice of the circuit elements used so that a high Life of the picture tube results. It will be shown in this regard that the filament voltage increases with the mentioned resistor-rectifier combination can be set so that the picture tube in the works with the optimal heating voltages in both operating states of the receiver.

In the following, exemplary embodiments of the invention are explained in more detail with reference to the drawing; it indicates

La is a circuit diagram of a preferred embodiment a power supply circuit that ensures immediate operational readiness for one TV receiver with thyristor deflection sound: mg,

Fig. Ib the sound image of a according to F ig. ia modified Aiisführuiigsform the invention, in which a independent control of the picture tube! lcizspannungc'ii is possible and

F i g. 2 and 3 alternative embodiments of the one used in the circuit arrangement according to FIG Resistor-rectifier combination with which the independent adjustment of the heating voltage is also possible can be effected.

In Fig. La, the AC voltage source serving to supply power to the receiver is through Terminals 10 shown to which an on-off switch 12 and a thermistor 14 are connected in series. the Thermistor 14 is used to limit the first connection of the receiver to the AC voltage network possible inrush currents. On the Thcrmisior 14 is followed by a semiconductor rectifier 16 and a pi filter 18. The pi filter 18 contains a capacitor 20, an inductor 22 and a capacitor 24. One terminal of the capacitors 20 and 24 are coupled to ground and the other terminal is coupled to opposite ends of inductor 22. When the anode of the semiconductor rectifier 16 is coupled to the thermistor 14 and these circuit components have the values given below, occurs when terminals 10 are supplied with a mains voltage of 115 V at the connection of the inductance 22 and the capacitor 24 a DC voltage of about + 140V.

Two sections 26a and 26b of the primary winding of an input transformer 26 and a line 28 are also coupled to the connection of the inductance 22 and the capacitor 24. The direct voltage occurring at the mentioned connection is fed through the line 28 to a line oscillator stage 30 and is used there as the operating voltage for a transistor 32 of this stage. The line oscillator stage 30 works as a blocking oscillator, the emitter electrode of the transistor 32 being grounded * and the collector electrode being supplied with the DC voltage via a resistor 34 and a first winding 36.Ί of a transistor 36. One end of a second winding 366 of the transformer 36 is grounded and the other end is connected to an output terminal 40 via a capacitor 38. Appropriate input signals are sent to the base electrode of transistor 32 via a capacitor

Sator 41 and a third winding 36c of the transformer 36 are supplied. The oscillator circuit described is known in principle; further details can be found in the publication “Solid State Color Television-CTC 400 Chassis ", 1968 of the RCA Sales Corporation of Indianapolis, Indiana, V. St. A.

The output terminal 40 is in turn connected to the control electrode of a first thyristor 42 whose cathode is connected to ground and whose anode is connected to the cathode of a semiconductor diode 44 whose anode is connected to ground. This parallel circuit 42-44 forms the polarity reversal switch of two in both directions of current conductive Schaltvorrichtungcn according to the teachings of US-PS 34 52 244. As shown, the connection of the anode of the thyristor 42 with the cathode of the diode 44 to the section 26 '; the end of the section 266 of this winding facing away from the primary winding of the transformer 26.

The junction of sections 26; j and 266 is in turn coupled to the control electrode of a second thyristor 46, which is a second semiconductor diode 48 is connected in parallel with opposite polarity. More precisely is the connection of the sections 26 <'i and 266 of the primary winding of the transformer 26 Via the series connection of a capacitor 50 and an inductance 52 with the control electrode of the Thyristor 46 connected, and the connection of components 50 and 52 is through a resistor 54 with Ground coupled. The anode of the thyristor 46 is connected to the cathode of the diode 48 which is grounded with its anode connected and the parallel combination 46-48 forms the in-line switch of the bidirectional switching device according to US-PS 34 52 244. The anode of the thyristor 46 is also via a capacitor 56 and an inductor 58 coupled to the anode of the thyristor 42 and the resulting circuitry is as far as it is the switching devices that are in both Directions to conduct electricity, gun / similar to that described in the aforementioned U.S. patent is when a capacitor 60 between the connection of the capacitor 56 and the inductor 58 on the one hand and ground on the other hand is connected.

The semi-silver piece receiver also reveals Zcilenablenkspulcn 62, which have a Lincariiätskor correction serving inductance 64 and a / for generating an S-shaped Slromverlaul's serving Capacitor 66 are connected between the anode of thyristor 46 and ground. The combination of the Zcilcnablenkspulen 62, the inductance 64 and the capacitor 66 is a primary winding 68 "of a jo Line transformer 68 connected in parallel, similar to it is described in the aforementioned USA patent.

The operation of the circuit arrangement described so far corresponds to that of US Pat. No. 3,452,244 in every respect. The transistor 32 of the line oscillator stage is blocked by pulses from its collector electrode, which are coupled into its base circuit via the transformer 36. While the transistor 32 is blocked in this way, the capacitor 41 emits a current pulse which appears in the collector circuit of the transistor 32 and is fed back via the transformer 36 to the base circuit in order to initiate the saturation of the transistor of the oscillator stage. The trace switch consisting of the thyristor 46 and the diode 48 switches the capacitor 66, which is used to generate a Sformigcn SliOmverlitufs, the Zcilcnablenkspulen 62 during the running of each deflection cycle, while the return switch from the thyristor 42 and the diode 44, the capacitor 46 during the return part the line deflection coils 62 connected in parallel. The capacitor 56 and the polarity reversal inductance 58 are connected between the outgoing and return switches, the DC supply voltage from the connection between the inductance 22 and the capacitor 24 of the connection of the return switch to the inductance 58 via the relatively large inductance of the sections 26, - j and 266 is fed to the primary winding of the transformer 26.

As explained in detail in the aforementioned USA patent, a complete cycle of the results Line deflection coil currents from a sequence of individual processes in which different modes of operation play along with the line deflection. At the introduction of the trace interval of each line deflection cycle, the current flowing in the line deflection coils 62 therefore has as a result of earlier processes in the deflection circuit, in which an exchange of resonance energy between the Inductors 58, 26;) and 266, the capacitors 56 and 60 and the 2xilenablenkspulcn 62 took place, one Maximum value. The deflection coil current at this time flows in a manner indicated by an arrow / 1 Direction and through the diode 48 of the trace switch in the capacitor 66, at which a voltage of the specified polarity prevails.

Approximately in the middle of the trace (the center of the scanned raster) the current A becomes zero, and the thyristor 26 is through the section 26 £> the Primary winding of the condenser 26 and the circuit arrangement with the condenser 50, the inductance 52 and the resistor 54 keyed. At this point the capacitor 66 discharges through the Line deflection coils, a current flowing in the direction indicated by the arrow / 2, which the diode 48 in Spcrrichttmg, but at the same time applied to the thyristor 46 in the direction of flight.

During the latter part of the linear interval and before the retraction, a pulse is generated at the winding 36b of the transformer 36 in the oscillator stage 30, which is fed to the control electrode of the thyristor 42, which is applied and the polarity reversal of the deflection cycle is initiated. During this particular cell span, both the thyristor 46 and the thyristor 42 conduct, but the current from the polarity reversal circuit increases faster than the current h from the line deflection coils, so that the direction of the resulting current flowing through the thyristor 46 changes according to its short line reversed and the thyristor 46 is blocked. Since the current in the polarity reversal is currently greater than the current in the Zcilcnablenkspulen the diode 48 is biased in the direction of flow and then conducts. However, it only carries current for a very short period of time, namely until the current drops in polarity reversal and becomes equal to the deflection coil current. The diode 48 then becomes non-conductive again around the beginning of the return interval.

During the first half of the return period! when both thyristor 46 and diode 48 are gcspprr, the resulting visual disorder forms a series rosonnzkreis from the inductance 58th den Capacitor 56 and Zcilcnablenkspulen 62, whose fine tuning by the capacitor 60 determines will. (The capacitor 66 is also in series with the components mentioned because of its large size Its influence, however, can be just as negligible as the influence of uncarity

serving inductance 64.) In the middle of the retrace interval the current in the series resonant circuit becomes zero and reverses its direction, whereby the thyristor 42 is blocked, since the current now flows in a direction opposite to its flow direction. However, the diode 44 is then forward biased and begins to conduct, thereby completing the circuit for the remainder of the return current. The energy that was stored in the capacitor 56 during this interval is therefore fed back into the line deflection coils 62. At the end of the retrace interval, the voltage developed across the diode 48 can bias it in the forward direction and switch it into the conductive state. As a result, the polarity reversal components 56, 58 are practically switched off by the Zcilenablenkspulen 62 and the capacitor 66 connected in parallel with these coils. The energy of the line deflection coils then discharges into the capacitor 66 and the first half of the next trace interval begins.

This complex sequence of energy exchange processes between the various formwork components is explained in detail in US Pat. No. 3,452,244, to which reference is expressly made here. ² pp

As will be apparent from the following explanations, the circuit arrangement according to FIG. 1 a differs from that according to the above-mentioned Palentschrift in that the transformer 26 is given away with two additional windings and that the inliner 46-48 has an on-off control device for the receiver is connected in parallel. The transformer 26 contains a third winding 26c- as a secondary winding, one terminal of which is connected to ground and the other terminal of which is connected to a diode 80 bridged by a capacitor 82 . The cathode of the diode 80 is in turn coupled to a terminal 5 of a two-pole changeover switch 90 via a isolating circuit which reveals a resistor 84 and a capacitor 86. With the values given in the table at the end of the description for these circuit elements, a DC voltage of around I 44 volts occurs at terminal 5.

A further secondary winding 26i /, which is arranged at section 26 /) of the primary winding, is also coupled to the transformer 26. The terminals of the winding 26 (/ is a Capacitor 92 geschallet parallel and in them occurs a substantially rechlcckwellcnförmigc AC voltage. Serving as a heating voltage to the filament of a picture tube 94th The on-off switch for the receiver by clamping 1.2 and 3 of the two-pole changeover switch 90, with terminal I being free, terminal 2 being connected to ground and terminal 3 being connected to the anode of the thyrislors 46. As will soon be seen, the receiver is switched off when the Changeover switch 90 is in the position in which terminals 2 and 3 on the one hand and terminals 5 and 6 on the other hand are connected by mechanically interconnected movable contact pieces " on the one hand and terminals 4 and 5 on the other hand ("open" position of switch 90), the receiver is switched on.

Terminals 1 and 6 of changeover switch 90 are not wired. The terminal 4 is through a resistor 9b with a basic attitude 98 of the Repflln ·

fts gers, in particular the collector electrode of a transistor 100 contained in this circuit. The emitter electrode of the transistor 100 is connected to one of two series-connected resistors 102 and 104 , at the connection of which a vertical deflection signal occurs. Resistor 104 is in turn connected to the collector of a second transistor 106 in the vertical deflection circuit. The connection of resistor 96 to the collector of transistor 100 is coupled to ground via a filter capacitor 108. It is evident that when the receiver is switched on, i.e. when terminals 4 and 5 of changeover switch 90 are connected to one another, the positive DC voltage at terminal 5 feeds transistors 100 and 106 and enables vertical deflection signals to be generated. When the receiver is switched off, on the other hand, the connection between the DC voltage of a terminal 5 and terminal 4 is interrupted and the stage 98, which is thus de-energized, cannot generate any vertical deflection signals. A voltage of about +35 volts is applied in transistor 100 when terminals 4 and 5 are connected.

In Fig. 1 also shows circuit arrangements which can be controlled by the changeover switch 90 and which supply a DC supply voltage for the video stages of the television receiver and the driver stages of its picture tube. The video part 110 , which is only shown schematically and partially, typically contains a amplifier stage with a transistor 112, the base electrode of which is supplied via a delay line 114 with luminance signals. The emitter electrode of the transistor 1 12 is connected through a resistor I lfi to ground, while the Kollcktorclcklrodc this transistor with a Fillerkondensator 122 and a resistor is connected 118, whose other terminal is connected to the terminal 4 of the switch 9 (. 1 As in the case of the vertical end column 9Ϊ the Kollcktorclcklrodc of the transistor 112 receives a supply voltage equalization only in that operating position of the switch 90, in which the terminals 4 and 5 are connected. The resistor 118 connected to the capacitor 122 is also used to reduce the voltage from +44 full, which prevails at terminal .1, to +30 volts, as required for the supply de; Vidcoteils IU).

The driver stage 124 for the picture tube contains a transistor 126, the collector electrode of which is connected to a secondary winding 68 /) de: ZcUciUransfurmaturs 68 via a resistor 128 . One terminal of this secondary winding is connected to ground, while the other terminal is connected to the anode of a semiconductor diode 13 (to which a capacitor 132 is connected. The cathode of the diode 130 is connected to the resistor 128 and a capacitor 136 leading to ground. The diode 130, the capacitor 132 and the capacitor 136 generate a DC supply voltage for the collector block of the transistor 126, except when the terminals 1 and 3 of the changeover switch 90 are connected 68 and the capacitor 70 are practically short-circuited by the switch and no signal is induced in the secondary winding (J8 / j, as is required for the power supply of the driver stage 124).

The flyback transformer 68 also has a < further winding 68c, on which return pulses are available for use in the television receiver

709 62Θ / 19th

stand, ζ. B. for automatic frequency control and the high voltage generation.

The circuit arrangement described thus contains a deflection system with two thyristors, the input power of which or operating voltage is obtained by the same direction of the mains voltage. It is neither a 60-Hertz-Net2: transformer still has a heating transformer, since the heating voltage is supplied by a additional winding 26d is generated on the input transformer 26 and the other supply voltages under control of the two-pole changeover switch 90. If this is and switching off the receiver serving control device is set so that on the one hand the terminals 1 and 2 and, on the other hand, terminals 4 and S are connected through, become supply voltages for the vertical output stage 98, the video part 110 and the driver stage 124 for the picture tube and through the Transformer winding 68c generated for the high voltage supply. At the same time there is also a direct voltage for the line oscillator stage 30 is available. On the other hand, if this on-off control device does so it is set that terminals 2 and 3 on the one hand and terminals 5 and 6 on the other hand with one another are connected, the operating voltage of the vertical pin 98 and the video part 110 is switched off and the generation of a DC voltage for the driver stage 124 of the picture tube is then prevailing short circuit between the anode of the thyristor 46 and ground is prevented, eventually The generation of the high voltage is also prevented, since the flyback transformer 68 is practically switched off.

Nevertheless, the recipient described by the last Setting the toggle switch 90 is turned off, the line oscillator 30 continues to be through the positive DC voltage fed to the connection between the inductor 22 and the capacitor 24 is available. The Zci'enoszillaiorstiife JO therefore continues to work, the same applies to the polarity reversal switch with the thyristor 42 and the diode 44, so that the picture tube 94 via the transformer windings 26.7, 266 and 26c / is supplied with heating voltage. Through the Change of the time consiants that are in the voting circle with the circuit components 56, 58 and 60 occurs when the anode of the trace thyristor 46 through ilen Changeover switch 90 is short-circuited to ground, the polarity reversal circuit supplies a different voltage than with the receiver switched on. By appropriate choice of the values of the capacitors 56 and 60 and the Inductance 58 can be that supplied to picture tube 94 Power can be adjusted. When using the line partimeters given below, the voltage is the filament of the picture tube with the receiver switched on (terminals I and 2 as well as terminals 4 and 5 of the switch 90 through-connected) is supplied, on the order of 6 full. In the »Wunc / usinnd«, if the fighter is switched to "Alis" and the Terminals 2 and 3 and 5 and 6 of the switch 90 are connected through, the heating voltage is through the Change in time constant reduced to about 5 volts. It has been shown that the service life of the picture tube by such a reduction in the heating voltage compared to clem FnII that the The picture tube is continuously supplied with the full heating voltage when the receiver is switched off is extended, while at the same time the picture tube is able to switch the switch 90 to the "F.in" position reaches its fullest speed To achieve emissivity that is comparable to that of the simultaneously supplied with operating voltage semiconductor-equipped steps need to be responsive.

Because of the change in the coordination of the polarity reversal circle in the "Off" position of the switch 90, the heating power is set to one for waiting. appropriate amount and the total power consumption of the system is significantly reduced. By appropriate choice of the number dci turns of the heating winding of the transformer 2 (and / or the inductance of the deflection coil set can be obtained a desired range of the heating voltage of terminals 2 and ': interrupted and terminals 4 and 5 are connected through.

The bridging of the outgoing Thyri stors 46 described by the on and off serving Changeover switch 90 has the further advantage that current peaks caused by the control or switching process can occur in comparison / u the usual circuits in which the on-off switch is in series with the management, be significantly degraded. Since, in addition, toggling the toggle switch: 90 to the "Off" position, at which terminals 2 and. are connected to the generation of high voltage egg through the flyback transformer 68 immediately and before clii other supply voltages drop, is interrupted, the capacity of the high voltage is discharged electrode of the picture tube more completely and one therefore came to the previously used ci Do without high-voltage discharge resistors.

In the practically implemented Alisführungform de circuit arrangement according to Fig. La cut the scarf liingsparameter which are populated in the following table ' ten values, which of course are not to be interpreted as limiting.

Table I.

Resistor J4
Resistance 54
Resistance 84

Resistance 96
Resistance 102
Resistance 104
Resistance 116
Resistance 118

Resistor 128
Capacitor 20
Capacitor 24
Capacitor 38
Capacitor 50

Capacitor 56
Capacitor 60
Capacitor 66
Capacitor 82
Capacitor 86

fio capacitor 108
Capacitor 122
Capacitor 132
Capacitor 136
Capacitor 138

Inductance 52
Inductance 58
Thermistor 14
Picture tube 94

5.6 kOhm 270 Ohm 4.7 Ohm 18 Ohm 0.1 Ohm 0.3 Ohm 3.4 kOhm b8Ohm lOkOhm

175 μΐ

0.15 nF 0.18 nF 0.75 µ F 0.047 µF 2.5 µ F 39OpF 100 μ F 1000 μ F 500 μ F 39OpF 10 μ F 0.OJJnF 470 μ 11 67 μΗ 40 Ohm I7VBLP2:

In the embodiment shown in Fig. Ib are a instead of the capacitor 92 (Fig. La) Resistor 300 and a rectifier 302 held in parallel with it use / wipe the winding 26 (7 of the transformer 26 and the filament of the picture tube 94 are connected. More precisely, this is Parallel connection between the upper terminal of the winding 26c / and the one connection of the Hei / I'adcns of the picture tube while the lower terminal of the winding 26t / with the other terminal of the Ilei / l'adens and a further capacitor 306 to ground via a further resistor 304 are coupled. The switchover of the opposing country 300 and the rectifier 302 have the particular purpose of both the picture tube 94 of the television receiver is in the operating state as well as in the switched-off state (waiting state) with optimal heating voltages take care of. The lower terminal of winding 26J is also connected to the through a further resistor 350 Connection between diode 130 and capacitor 136 coupled to the filament of the To supply picture tube 94 a correct DC voltage.

With the above Schaltuiigsparametern and with a mains voltage of the nominal value of 120 V at the terminals 10 were used for the picture tube 54 zugefi'ihne heating voltage in the off state of the Lmpfängers the Wen ^r> .l V and in the switched condition of the recipient, the value 5, 9 V measured. In the data sheets published by the manufacturer of the picture tube used here, however, the optimal heating ^{voltages required are 1} S ₁ OV or 6.0 V for all switched-off and switched-on states of the receiver. Operating the receiver with 5.1 or 5.9 V would therefore lead to a slightly shorter service life of the filament of the picture tube than if the time prescribed by the creator was kept exactly. The apparent solution that offers itself, namely to increase the number of turns of the winding 26 /) so that the heating voltage generated when the Lmpfäiiger is switched on is raised from 5.9 V to the recommended M) V, has a disadvantage that the idle voltage in the The switched-off state of the Lmplängers would also be increased compared to the measured 5.1 V, but this change is in a direction that is disadvantageous for the longest possible service life of the pipes. If, on the other hand, the number of turns of winding 26 is reduced in order to bring the heating voltage in the switched-off state of 5.1 V closer to the optimal value of 5.0 V zn, the voltage that is the lead of the picture tube in the switched on state of the Lpffüngers is supplied, reduced in a corresponding manner.

A change in the number of turns of the winding 266 of the transformer 26 becinflul.lt the value of the heating voltage generated and it can also be seen that the ratio of the heating voltages in the switched-on and switched-off state of the receiver should be 1.2 for optimal operation, ie dull the heating voltage should rise from 5.0 V to bO V when the receiver is poured from "off" to "out". In connection with Kig. The circuit arrangement described in ta lies this ratio in the order of magnitude of 1.155, since the heating voltages are 5.9 and 5.1 V, respectively. In the school ring arrangement gcmUß I "ig. Ib it is provided that the number of turns of the winding 26 /) of the transformer 2h is so large that the idle voltage takes the setpoint value bO V when the television receiver is switched on The value of resistor 300 is then adjusted to si until the desired ratio of l _{v is} reached.

In the circuit arrangement with the resistor 300 and the rectifier 302, the rectifier 302 supplies the power for heating the filament of the picture tube 94 when the thyristor 42 is in the periodically occurring locked state, while the resistor 300 supplies the heating power for the picture tube 94 , while the rectifier 302 is reverse biased and the thyristor 42 is conducting. It was found that when the receiver is switched on and the circuit elements indicated below are used, the rectifier 302 provides 58.3% of the power for heating the filament of the Bildrölin and the contradicting 300 the remaining 41.7% of the power required. On the other hand, when the Lmp receiver was switched off, it was found that the rectifier 302 had 50% of the power for the periodic! Blocking intervals of the thyristor 42 and iler resistance 300 provide the remaining 50%. With the values given, the correct ratio is 1.2 µm . The required voltages of b and 5 V were measured on the picture tube.

Since the number of turns of the winding 26/5 can practically only be changed in two discrete steps by the voltage supplied by it, it is easily possible that the picture tube 94 is switched on! State of the recipient more than the required b \ are supplied. For such cases, an additional resistor .110 is connected in series with the rectifier 302 and this series connection is bridged with the resistor 300 in order to reduce the voltage generated; to be reduced to ilen setpoint of b V. Line such circuitry is in place. 2 and an alternative construction is shown by Hg. In this second alternative, there is the additional willingness, which is denoted here by? I2. between the upper winding 26 (/ and the parallel connection of the willingness 300 and the diode 502 is sounded. The connection of these additional voluntary circuits 110 or 312 influences the ratio of the ziigelühnei! leizspaimungen, so that the value of the opposing state 50 (can be adjusted again must until the correct 1 "IN / ΛIIS ratio is reached again. In the case of practical exemplary embodiments for which the switching parameters are listed in the following table, an additional resistor 3K or 312 was not required to achieve the desired cooling ratio and to achieve the desired Spanuur.gs values.

In the case of the above-described attitude disorder give a satisfactory operation with scarf Conversion of the following words, which of course are not to be interpreted restrictively.

table

Resistance 300 Resistor 304, Capacitor 306 Resistance 350

3.6 ohms
ISOkOhm
0.1 µ F
ISOkOhm

Such disordered attitudes, resistance unc additionally reveal rectifier in order to tubes mi various security spam values in the eye here gcgcnO.be have taken into account the above-mentioned ways SchiiltungsanordiHingeii, where only one

Resistance to the coupling of the Translorntaloi winding 26d with the cathode ray tube 94 filament The advantage is that the line losses when you generate the correct heating voltages are essential are smaller. Namely, it was found that bu M.k-hrn circuit arrangements mn a single Resistance throughout the orderly, appropriate Operating performance loss of some IO Wall

appear.

For this purpose 2 sheets of drawings

Claims (14)

Patent claims: I. Circuit arrangement for heating the picture tube of a television receiver with a switch that can be switched between reception and readiness, in the receiving position of which the picture tube is supplied with the full heating voltage and in its standby position the picture tube is supplied with a reduced heating voltage, characterized in that the receiver is a known one Line deflection circuit with a first and a second deflection switch (trace switch 46, 48 and return switch 42, 44), the second of which is controlled by a Zcilcnoszillator (30), indicates that a first coupling circuit (266, 26d) between a voltage source (10) and the heating circuit the picture tube (94) and connected to the second deflection switch (42, 44) for heating energy supply depending on the duty ratio of the two deflection switches, and that a second coupling circuit (26 ;;, 26c,) with the voltage source (10) and the switch (90), which in turn is connected to the first en deflection switch (46, 48) and circuit units (98, 110) to be supplied with operating voltage are connected in such a way that energy is only supplied to them in the receiving position and in the standby position the first deflection switch (46, 48) to change the switching ratio of the two deflection switches in the In order to reduce the picture tube heating voltage, it is put out of operation, while the second deflection switch (42, 44) is still controlled by the line oscillator (30), which is also in the standby position. 2. Circuit arrangement according to claim 1, characterized in that with the two deflection switches (42, 44; 46, 48) a timer (56, 58. 60) is coupled, which in the receiving position of the Changeover switch (90) influences the line deflection current, in the standby position, however, the picture tube heating voltage degrades. 3. Circuit arrangement according to claim 1, characterized in that the two deflection switches (42, 44; 46, 48) are conductive switches in both current directions. 4. Circuit arrangement according to claim 3, characterized in that the two deflection switches (42, 44; 46, 48) each have an anti-parallel circuit made up of a controllable silicon rectifier or thyristor (42 or 46) with a diode (44 or 48). 5. Circuit arrangement according to claim 4, characterized in that a time control circuit (50, 52, 54) for switching on the thyristor (46) of the first deflection switch (46, 48) approximately in the middle of the line trace interval between the first coupling circuit (26b, 26d ) and the thyristor (46) is connected. 6. Circuit arrangement according to claim 5, characterized in that the diode (48) of the first Deflection switch (46, 48) is polarized such that during the first half of the line trace interval for the current flowing through the line deflection winding (62) is permeable. 7. Circuit arrangement according to claim 6, characterized in that the thyristor (42) of the second Deflection switch (42, 44) is polarized so that it is immediately before and during an initial Part of the line retrace interval is conductive. 8. Circuit arrangement according to claim 7, characterized in that the diode (44) of the second Deflection switch (42, 44) is connected anti-parallel to the associated thyristor (42). 9.Schaltung arrangement according to claim!, Characterized in that a first Koppclschallung (266, 26d) is assigned an Impedan / Schahung (300, 302, 304, 306) which is coupled to the filament of the picture tube (94) and with the help of the the heating voltage of the picture tube (94) and the heating voltage ratio in the standby or receiving position is determined. 10. Circuit arrangement according to claim 9, characterized in that the impedance circuit contains a resistive current path (300) and a rectifying current path (302), which the filament of the picture tube (94) in a series freeze circle with an inductive winding (26o7 of the first coupling circuit (266,26c / jswitch. 11. Circuit arrangement according to claim 9, characterized characterized in that between the hot filaments of the picture tube (94) and one at reference potential (z. B. ground) lying circuit point the parallel connection of a capacitor (306) with a Resistor (304) is connected. 12. Circuit arrangement according to claim 9, characterized in that the impedance circuit a parallel connection of a first resistor (300) with a diode (302) included in a Series circuit between one connection of the inductive winding (26c ^ and the heater of the Picture tube (94) lie. ! 3. Circuit arrangement according to Claim 12, characterized in that in parallel with the first Resistor (300) is a series circuit of a second resistor (310) with the diode (302). 14. Circuit arrangement according to claim 12, characterized in that between the inductive Winding (26djand the parallel connection of the first Resistor (300) with the diode (302) a second resistor (312) is inserted. ! 5. Circuit arrangement according to Claim 9, characterized in that the heating filament is the Picture tube (94) via an impedance (350) to the operating voltage for a driver stage (124) of the Picture tube (94) is connected.